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Masters Degrees (Radio Frequency And Microwave Engineering)

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Surrey is one of very few institutions with the expertise and facilities to give you hands-on experience in RF and microwave devices, backed and informed by pioneering research in wireless communications, space technology, advanced gigahertz and terahertz microwave technologies. Read more
Surrey is one of very few institutions with the expertise and facilities to give you hands-on experience in RF and microwave devices, backed and informed by pioneering research in wireless communications, space technology, advanced gigahertz and terahertz microwave technologies.

This programme emphasises radio and microwave communications in 5G and beyond.

PROGRAMME OVERVIEW

This programme addresses the great shortage of skilled radio frequency (RF) and microwave engineers, and the growing demand for conceptually new wireless systems.

You will learn about a range of modern theories and techniques, accompanied by topics on wireless frequencies and sizes of RF and microwave devices.

This ranges from the lowest frequencies used in radio frequency identification (RFID) systems through to systems used at mm wave frequencies that can have applications in satellite communication systems and fifth generation wireless communication systems.

Theoretical concepts established in lectures are complemented by practical implementation in laboratory sessions, with direct experience of industry-standard computer-aided design (CAD) software.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a project. The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.
-RF and Microwave Fundamentals
-Nanoscience and Nanotechnology
-Antennas and Propagation
-Fundamentals of Mobile Communications
-Principles of Telecommunications and Packet Networks
-Satellite Communication Fundamentals
-RF Systems and Circuit Design
-Advanced Mobile Communication Systems
-Microwave Engineering
-Nanoelectronics and Devices
-Advanced Satellite Communication Techniques
-Standard Project

ACADEMIC SUPPORT

We provide solid academic support through the taught modules and into the project period. You will be assigned a personal tutor with whom you can discuss both academic and general issues related to the programme.

When you move into the project phase of the programme, you will be assigned a project supervisor who you will meet, usually on a weekly basis, to discuss the progress of your project.

The individual taught modules also feature strong academic support, usually through a tutorial programme. All of the RF and microwave modules have tutorial sheets to support the lectures.

Although completing the tutorials is not part of the formal assessment, you have the option of using the tutorials to receive individual feedback on your progress in the modules.

FACILITIES AND EQUIPMENT

The combined facilities of the RF teaching laboratories and the Advanced Technology Institute provide MSc students with an exceptionally wide range of modern fabrication and measurement equipment.

Furthermore a wide variety of RF test and measurement facilities are available through Surrey Space Centre and the 5G Innovation Centre, which also involve work in the RF and microwave engineering domain.

Equipment includes access to CAD design tools, anechoic chamber, spectrum analysers, network analysers, wideband channel sounder, circuit etching and circuit testing.

INDUSTRIAL AND OVERSEAS LINKS

The 5G Innovation Centre and Advanced Technology Institute within the Department have a range of active links with industry, both in the UK and overseas. During the past few years we have had students taking the MSc through the part-time route and completing their projects in industry.

Examples of industrial projects range from looking at new microwave measurement techniques at the National Physical Laboratory (NPL), to antenna design and construction at the Defence Science and Technology Laboratory (Dstl).

We have also sent students overseas to complete their projects, funded through the Erasmus scheme, which is a European programme that provides full financial support for students completing their project work at one of our partner universities in mainland Europe.

Students taking advantage of this opportunity not only enhance their CVs with a European perspective, but also produce excellent project dissertations.

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

General transferable skills
-Be able to use computers and basic IT tools effectively
-Be able to retrieve information from written and electronic sources
-Be able to apply critical but constructive thinking to received information
-Be able to study and learn effectively
-Be able to communicate effectively in writing and by oral presentations
-Be able to present quantitative data effectively, using appropriate methods
-Be able to manage own time and resources
-Be able to develop, monitor and update a plan, in the light of changing circumstances
-Be able to reflect on own learning and performance, and plan its development/improvement, as a foundation for life-long learning

Underpinning learning
-Know and understand scientific principles necessary to underpin their education in electronic and electrical engineering, to enable appreciation of its scientific and engineering content, and to support their understanding of historical, current and future developments
-Know and understand the mathematical principles necessary to underpin their education in electronic and electrical engineering and to enable them to apply mathematical methods, tools and notations proficiently in the analysis and solution of engineering problems
-Be able to apply and integrate knowledge and understanding of other engineering disciplines to support study of electronic and electrical engineering.

Engineering problem-solving
-Understand electronic and electrical engineering principles and be able to apply them to analyse key engineering processes
-Be able to identify, classify and describe the performance of systems and components through the use of analytical methods and modelling techniques
-Be able to apply mathematical and computer-based models to solve problems in electronic and electrical engineering, and be able to assess the limitations of particular cases
-Be able to apply quantitative methods relevant to electronic and electrical engineering, in order to solve engineering problems
-Understand and be able to apply a systems approach to electronic and electrical engineering problems

Engineering tools
-Have relevant workshop and laboratory skills
-Be able to write simple computer programs, be aware of the nature of microprocessor programming, and be aware of the nature of software design
-Be able to apply computer software packages relevant to electronic and electrical engineering, in order to solve engineering problems

Technical expertise
-Know and understand the facts, concepts, conventions, principles, mathematics and applications of the range of electronic and electrical engineering topics he/she has chosen to study
-Know the characteristics of particular materials, equipment, processes or products
-Have thorough understanding of current practice and limitations, and some appreciation of likely future developments
-Be aware of developing technologies related to electronic and electrical engineering
-Have comprehensive understanding of the scientific principles of electronic engineering and related disciplines
-Have comprehensive knowledge and understanding of mathematical and computer models relevant to electronic and electrical engineering, and an appreciation of their limitations
-Know and understand, at Master's level, the facts, concepts, conventions, principles, mathematics and applications of a range of engineering topics that he/she has chosen to study
-Have extensive knowledge of a wide range of engineering materials and components
-Understand concepts from a range of areas including some from outside engineering, and be able to apply them effectively in engineering projects

Societal and environmental context
-Understand the requirement for engineering activities to promote sustainable development
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk issues
-Understand the need for a high level of professional and ethical conduct in engineering

Employment context
-Know and understand the commercial and economic context of electronic and electrical engineering processes
-Understand the contexts in which engineering knowledge can be applied (e.g. operations and management, technology development, etc.)
-Be aware of the nature of intellectual property
-Understand appropriate codes of practice and industry standards
-Be aware of quality issues
-Be able to apply engineering techniques taking account of a range of commercial and industrial constraints
-Understand the basics of financial accounting procedures relevant to engineering project work
-Be able to make general evaluations of commercial risks through some understanding of the basis of such risks
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk) issues

Research and development
-Understand the use of technical literature and other information sources
-Be aware of the need, in appropriate cases, for experimentation during scientific investigations and during engineering development
-Be able to use fundamental knowledge to investigate new and emerging technologies
-Be able to extract data pertinent to an unfamiliar problem, and employ this data in solving the problem, using computer-based engineering tools when appropriate
-Be able to work with technical uncertainty

Design
-Understand the nature of the engineering design process
-Investigate and define a problem and identify constraints, including environmental and sustainability limitations, and health and safety and risk assessment issues
-Understand customer and user needs and the importance of considerations such as aesthetics
-Identify and manage cost drivers
-Use creativity to establish innovative solutions
-Ensure fitness for purpose and all aspects of the problem including production, operation, maintenance and disposal
-Manage the design process and evaluate outcomes
-Have wide knowledge and comprehensive understanding of design processes and methodologies and be able to apply and adapt them in unfamiliar situations
-Be able to generate an innovative design for products, systems, components or processes, to fulfil new needs

Project management
-Be able to work as a member of a team
-Be able to exercise leadership in a team
-Be able to work in a multidisciplinary environment
-Know about management techniques that may be used to achieve engineering objectives within the commercial and economic context of engineering processes
-Have extensive knowledge and understanding of management and business practices, and their limitations, and how these may be applied appropriately

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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This programme will not have a 2016 intake as the content is being extensively improved. A one-year course that will provide engineering and science graduates with a thorough knowledge of modern radio and mobile communication systems. Read more

NOTE

This programme will not have a 2016 intake as the content is being extensively improved.

A one-year course that will provide engineering and science graduates with a thorough knowledge of modern radio and mobile communication systems.

AIM OF COURSE

Mobile radio encompasses a diversity of communications requirements and technical solutions including cellular mobile radio and data systems (eg GSM, GPRS, 3G, 4G, WiMax) and Personal Mobile Radio as well as various indoor radio systems including Bluetooth, WIFI, Wireless Indoor Networks (WINs or LANs). In view of the huge size of the market for these enhanced systems providing flexible personal communications, it is important that industry equips itself to meet this challenge. This MSc course aims to provide industry with graduates who possess a thorough knowledge both of actual modern radio systems and of the fundamental principles and design constraints embodied in those systems.

COURSE STRUCTURE

The course spans 50 weeks of full-time study and is divided into teaching and project modules. The teaching block is based on 6 modular courses, each comprising approximately 40 hours of lectures (or lecture equivalents) with additional directed study and practical work. All of these modules are augmented by specific case studies, applications and tutorials.

COURSE HIGHLIGHTS

Radio Systems Engineering
A radio receiver design is analysed in detail so that design compromises may be understood. Topics include gain, selectivity, noise figure, dynamic range, intermodulation, spurious output, receiver structures, mixers, oscillators, PLL synthesis, filters and future design trends. This course also includes familiarisation with industry - standard design packages. Introduces key concepts in conventional and novel antenna design. It incovers the following topics: basic antenna structures (eg wire, reflector, patch and helical antennas); design considerations for fixed and mobile communication systems; phased array antennas; conformal and volume arrays; array factor and pattern multiplication; mutual coupling; isolated and embedded element patterns; active match; true time delay systems; pattern synthesis techniques; adaptive antennas; adaptive beamforming and nulling.

Mobile Radio Systems and Propagation
The aim of this module is to investigate the nature of radio propagation in mobile radio environments. This will be achieved through the examination of several modern mobile radio systems. The effects of the propagation environment will also be considered.

Spectrum Management and Utilization
The electromagnetic spectrum is a finite resource which has to be properly managed. This module will address issues related to spectrum management. Topics covered will include: spectrum as a resource; space, time and bandwidth; international regulation organisations and control methods; definitions of spectrum utilisation and spectrum utilisation efficiency; spectrum-consuming properties of radio systems; protection ratio; frequency dependent rejection and the F-D curve; spectrum management tools, models and databases; spectrally-efficient techniques; efficient use of the spectrum.

Electromagnetic Compatability (EMC)
This module provides an introduction to EMC. Topics include fundamental EM interactions and how these give rise to potential incompatibilities between systems; current EMC legislation; test environments and test facilities.

Communication Systems and Digital Signal Processing
Students are introduced to a range of concepts underpinning communications system design. DSP topics include the theory and applications of: real-time DSP concepts/devices; specialist filter applications; A/D and D/A interface technology; review of Fourier/digital filter applicable to DSP; modem design: modulation, demodulation, synchronisation, equalisation; signal analysis and synthesis in time and frequency domain; hands-on experience of DSP tools and DSP applications.

Low Power/Low Voltage Design and VHDL
This module introduces the low power and low voltage design requirements brought about by increasingly small scale sizes of circuit integration. The module also introduces students to VHDL, which is widely used in industry today.

Design Exercise (RF Engineering)
This self-contained exercise aims to introduce the student to aspects of RF engineering, system specification, design and implementation. A design, such as a 2GHz receiver, will be taken through to practical implementation.

Radio Frequency and Microwave Measurements
This covers the theory of EM waves, propagation and scattering. It introduces the student to methods and instruments to measure important EM wave properties such as power and reflection coeffcients.

Active RF and Microwave Circuits
This module provides the student with an appreciation of; noise in microwave systems (basic theory, sources of noise, noise power and temperature, noise figure and measurement of noise); detectors and mixers (diodes and rectification, PIN diodes, single ended mixers, balanced mixers, intermodulation products); microwave amplifiers and oscillators (microwave bipolar transistors and FETs, gain and stability, power gain, design of single stage transistor amlifier, conjugate matching, low noise amplifier design and transistor oscillator design).

PROJECT MODULE
Following a course on research skills and project planning, each student carries out one major project from Easter to September focusing on a real industrial problem. Some projects are carried out ‘on-site’ with our local and national industrial partners. The basics of project planning and structure are taught and supervision will be given whilst the student is writing a dissertation for submission at the end of the course.

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This Masters in Telecommunications Engineering is accredited by IET and meets Chartered Engineer Status. Excel in the latest telecommunications technologies on this industry focused Liverpool John Moores University postgraduate course. Read more
This Masters in Telecommunications Engineering is accredited by IET and meets Chartered Engineer Status. Excel in the latest telecommunications technologies on this industry focused Liverpool John Moores University postgraduate course

•Complete this masters degree in one year (full time)
•Study at one the UK’s leading Engineering Schools
•Accredited by the Institution of Engineering and Technology (IET) and meets Chartered Engineer requirements
•Programme informed by internationally-acclaimed research in LJMU’s Electrical and Electronic Engineering Research Centre
•Close industry links
•Excellent career opportunities for positions including system designers, analysts, and senior engineers in the fields communications, computer networks and telecommunications

The MSc in Telecommunications Engineering is designed to develop engineers for the telecommunications industry who are able to design, commission, and manage telecommunications systems.

The programme benefits from being delivered by academics from LJMU’s School of Engineering, Technology and Maritime Operations, the General Engineering Research Institute (GERI) and the School of Computing and Mathematical Sciences.

The course team has strong industrial links and has established an international research profile. This is reflected in the programme securing accreditation by the Institution of Engineering and Technology (IET) - formerly the IEE - to meet its requirements for Chartered Engineer status.

The course covers radio frequency and microwave technologies, electronics and communications technologies, computer networks and wireless computing, and management.

The curriculum emphasises the application of the technologies and as such the course is supported by modern systems of modelling and simulation, an extensive laboratory programme and lectures from industrial experts.

You will have an opportunity to complete industrially-based projects and work experience in the areas of microwave, optical sensing, instrumentation, antenna design, etc.

Most of the MSc projects are undertaken in the Radio Frequency and Microwave research group within the General Engineering Research Institute. Research interests are concentrated into six main areas: Radio Frequency and Microwave (RFM) Applications, Underwater Communications, Radio Frequency Identification Technology (RFID) and wireless Applications, Sustainable Technologies, Non-destructive sensing and Terahertz laser sources.

LJMU’s international reputation in this field is reflected in the substantial research funds secured from the UK Engineering and Physical Sciences Research Council (EPSRC), Department of Trade and Industry, Envirolink, European Community and directly from industry including BP, United Utilities, Organon, Protensive, MercaChem and Biotage, Aspen Electronic, Anritsu and NEL.

Please see guidance below on core and option modules for further information on what you will study.
Level 7
Digital communications systems
Wireless networks and technologies
Telecommunications systems
Networks and protocols
Transmission media
Research skills
Modelling with Matlab and Simulink
MSc project
Advanced signal processing
Operations research
Safety and reliability
Project management
Programming for engineering
LabVIEW
Professional and leadership skills


Further guidance on modules
The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Academic Framework reviews are conducted by LJMU from time to time to ensure that academic standards continue to be maintained. A review is currently in progress and will be operational for the academic year 2016/2017. Final details of this programme’s designated core and option modules will be made available on LJMU’s website as soon as possible and prior to formal enrolment for the academic year 2016/2017.

Please email if you require further guidance or clarification.

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This programme is suitable for recent graduates and engineers with experience of microelectronics who have good mathematical ability. Read more
This programme is suitable for recent graduates and engineers with experience of microelectronics who have good mathematical ability. It provides a thorough knowledge of the principles and techniques of this exciting field and has been developed in consultation with industry advisors to ensure it is relevant to today’s workplace.

Modules are block taught so can also be studied separately by working engineers as continuous professional development either to enhance their knowledge in particular subject fields or to widen their portfolio.

Core study areas include ASIC engineering, sensors and actuators, technology and verification of VLSI systems, embedded software development and an individual project.

Optional study areas include communication networks, information theory and coding, solar power, wind power, systems architecture, advanced FPGAs, DSP for software radio, advanced photovoltaics, mobile network technologies and advanced applications.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/electronic-electrical-engineering/

Programme modules

Compulsory Modules:
• ASIC Engineering
• Sensors and Actuators for Control
• Embedded Software Development
• Individual Project

Optional Modules (Choose five):
• Communication Networks
• Fundamentals of Digital Signal Processing
• Solar Power 1
• Wind Power 1
• Communications Channels
• DSP for Software Radio
• Imagineering
• Mobile Networks
• Advanced FPGAs
• Engineering Applications
• Systems Modelling for Control Engineering – new for 2015
• Radio Frequency and Microwave Integrated Circuit Design – new for 2015

Block-taught, individual modules are also highly suitable as CPD for professional engineers needing to fill a skills gap.

How you will learn

Compulsory modules provide a comprehensive understanding of modern microelectronics, embedded electronic systems, emerging technologies and their uses while the individual research project offers the chance to pursue a specialism in-depth. You’ll have access to advanced research knowledge and state of the art laboratories using industry standard software (Altera, Cadence, Mentor, Xilinx) so that you are prepared to enter a wide range of industry sectors on graduation.

- Assessment
Examinations are held in January and May, with coursework and group work assessments throughout the programme. The high practical content of this course is reflected in the inclusion of laboratory assessments and practical examinations. The individual research project is assessed by written report and viva voce in September.

Facilities

You’ll have access to laboratories, industry standard software (Altera, Cadence, Mentor Graphics, Xilinx) and hardware including equipment provided by Texas Instruments.

Careers and further study

Consultation with industry to craft the syllabus ensures that you’ll have an advantage in the job market. The in-depth knowledge acquired can be applied wherever embedded electronic systems are found including mobile phones (4/5G), acoustics, defence, medical instrumentation, radio and satellite communication and networked systems, control engineering, instrumentation, signal processing and telecommunications engineering.

Scholarships and bursaries

Scholarships and bursaries are available each year for UK/EU and international students who meet the criteria for award.

Why choose electronic, electrical and systems engineering at Loughborough?

We develop and nurture the world’s top engineering talent to meet the challenges of an increasingly complex world. All of our Masters programmes are accredited by one or more of the following professional bodies: the IET, IMechE, InstMC, Royal Aeronautical Society and the Energy Institute.

We carefully integrate our research and education programmes in order to support the technical and commercial needs of society and to extend the boundaries of current knowledge.

Consequently, our graduates are highly sought after by industry and commerce worldwide, and our programmes are consistently ranked as excellent in student surveys, including the National Student Survey, and independent assessments.

- Facilities
Our facilities are flexible and serve to enable our research and teaching as well as modest preproduction testing for industry.
Our extensive laboratories allow you the opportunity to gain crucial practical skills and experience in some of the latest electrical and electronic experimental facilities and using industry standard software.

- Research
We are passionate about our research and continually strive to strengthen and stimulate our portfolio. We have traditionally built our expertise around the themes of communications, energy and systems, critical areas where technology and engineering impact on modern life.

- Career prospects
90% of our graduates were in employment and/or further study six months after graduating. They go on to work with companies such as Accenture, BAE Systems, E.ON, ESB International, Hewlett Packard, Mitsubishi, Renewable Energy Systems Ltd, Rolls Royce and Siemens AG.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/electronic-electrical-engineering/

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This course aims to provide you with key, advanced level knowledge and skills that will allow you to succeed in the rapidly growing wireless and microwave communication industry. Read more
This course aims to provide you with key, advanced level knowledge and skills that will allow you to succeed in the rapidly growing wireless and microwave communication industry. You will also develop research skills and other related abilities, enhancing your general engineering competency, employability, and providing you with an excellent platform for career development, whether that be within industry or academic research.

More specifically, the programme aims to:

Develop expertise in new and evolving areas of microwave engineering including mobile communications and medical applications of microwaves.
Focus on areas including advanced computer aided design (CAD), measurement and characterisation and communication systems engineering.
Cover laboratory work and advanced engineering management alongside modules in radio frequency engineering, advanced fabrication and test, advanced communication systems and non-linear RF design and concepts.
Provide you with expertise in the areas of micro and nano-technology and optoelectronics.

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There is a significant demand in Engineers trained beyond the Bachelor level. MSc in Electronic Engineering provides a rational, flexibly structured and coherent postgraduate study. Read more

Overview

There is a significant demand in Engineers trained beyond the Bachelor level. MSc in Electronic Engineering provides a rational, flexibly structured and coherent postgraduate study. The students will achieve a profound knowledge base in a wide area of Electronic Engineering. In additions, they will develop wider skills in IT, communication, problem solving, team working and time/task management. As a result, the programme will provide a springboard to a successful career to the mutual benefit of the individual, the economy and society.

Aims and Objectives

To satisfy demand in Engineers trained beyond the Bachelor level;
To provide sound general knowledge in advanced Electronic Engineering;
To present an intellectual challenge to the students
To facilitate professional development of the student that will lead to a successful professional career.

Distinctive features

MSc in Electronic Engineering is for students who wish to study a generic programme which is not biased towards a specialization. It will provide advanced knowledge in a broad range of Electronic Engineering without being focussed on a particular area. The programme is very flexible with a large range of choice options to accommodate candidates’ preferences. The candidates will gain both subject-specific and more generic skills. The programme combines academic depth with current industrial practice in the context of real engineering applications.

Modular structure

The course conforms to the standard University of Hull structure, consisting of two taught semesters (the Diploma stage) followed by a substantial individual project. Core modules are compulsory; choice of optional modules is based on student preferences.

Core:

Product Planning and Design Exercise (Semester 1)
Complex Circuits and Systems (Semester 2)
Dissertation project

Options:

Advanced Digital Systems Design
Advanced Discreet Time Signal Processing and Integrated Circuit Design
Applied Optoelectronics
Advanced Control
Control and Robotics
Machine Vision
Communication Systems
Mobile Radio
Propagation and Antennas
Radio Frequency and Microwave Devices
Techniques and Measurements

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An MSc-level conversion programme for those with first degrees in numerate disciplines (e.g. Maths, Physics, others with some mathematics to pre-university level should enquire). Read more
An MSc-level conversion programme for those with first degrees in numerate disciplines (e.g. Maths, Physics, others with some mathematics to pre-university level should enquire). The programme targets producing engineers with the knowledge and skills required for working in the communications industry on programmable hardware, in particular. There is a high demand for people to fill such roles in communications and test & measure equipment vendors, and in many smaller companies developing devices for the internet of things.

The huge growth of interconnected devices expected in the Internet of Things and the goals of flexible, high-speed wireless connections for 5G mobile networks and beyond, require programmable, embedded electronics to play a vital role. From the development of small, intelligence sensors to the design of large-scale network hardware that can be functionally adaptive in software-defined networking, there is a huge demand for advanced embedded electronics knowledge and skills in the communications sector.

Visit the website https://www.kent.ac.uk/courses/postgraduate/1223/embedded-communications-engineering

About the School of Engineering and Digital Arts

The School of Engineering and Digital Arts successfully combines modern engineering and technology with the exciting field of digital media.

Established over 40 years ago, the School has developed a top-quality teaching and research base, receiving excellent ratings in both research and teaching assessments.

The School undertakes high-quality research that has had significant national and international impact, and our spread of expertise allows us to respond rapidly to new developments. Our 30 academic staff and over 130 postgraduate students and research staff provide an ideal focus to effectively support a high level of research activity. There is a thriving student population studying for postgraduate degrees in a friendly and supportive teaching and research environment.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

EL829 - Embedded Real-Time Operating Systems (15 credits)
EL849 - Research Methods & Project Design (30 credits)
EL893 - Reconfigurable Architectures (15 credits)
EL896 - Computer and Microcontroller Architectures (15 credits)
EL822 - Communication Networks (15 credits)
EL827 - Signal & Communication Theory II (15 credits)
EL871 - Digital Signal Processing (DSP) (15 credits)
EL872 - Wireless/Mobile Communications (15 credits)
EL873 - Broadband Networks (15 credits)
EL890 - MSc Project (60 credits)

Research areas

- Communications

The Group’s activities cover system and component technologies from microwave to terahertz frequencies. These include photonics, antennae and wireless components for a broad range of communication systems. The Group has extensive software research tools together with antenna anechoic chambers, network and spectrum analysers to millimetre wave frequencies and optical signal generation, processing and measurement facilities. Current research themes include:

- photonic components
- networks/wireless systems
- microwave and millimetre-wave systems
- antenna systems
- radio-over-fibre systems
- electromagnetic bandgaps and metamaterials
- frequency selective surfaces.

- Intelligent Interactions:

The Intelligent Interactions group has interests in all aspects of information engineering and human-machine interactions. It was formed in 2014 by the merger of the Image and Information Research Group and the Digital Media Research Group.

The group has an international reputation for its work in a number of key application areas. These include: image processing and vision, pattern recognition, interaction design, social, ubiquitous and mobile computing with a range of applications in security and biometrics, healthcare, e-learning, computer games, digital film and animation.

- Social and Affective Computing
- Assistive Robotics and Human-Robot Interaction
- Brain-Computer Interfaces
- Mobile, Ubiquitous and Pervasive Computing
- Sensor Networks and Data Analytics
- Biometric and Forensic Technologies
- Behaviour Models for Security
- Distributed Systems Security (Cloud Computing, Internet of Things)
- Advanced Pattern Recognition (medical imaging, document and handwriting recognition, animal biometrics)
- Computer Animation, Game Design and Game Technologies
- Virtual and Augmented Reality
- Digital Arts, Virtual Narratives.

- Instrumentation, Control and Embedded Systems:

The Instrumentation, Control and Embedded Systems Research Group comprises a mixture of highly experienced, young and vibrant academics working in three complementary research themes – embedded systems, instrumentation and control. The Group has established a major reputation in recent years for solving challenging scientific and technical problems across a range of industrial sectors, and has strong links with many European countries through EU-funded research programmes. The Group also has a history of industrial collaboration in the UK through Knowledge Transfer Partnerships.

The Group’s main expertise lies primarily in image processing, signal processing, embedded systems, optical sensors, neural networks, and systems on chip and advanced control. It is currently working in the following areas:

- monitoring and characterisation of combustion flames
- flow measurement of particulate solids
- medical instrumentation
- control of autonomous vehicles
- control of time-delay systems
- high-speed architectures for real-time image processing
- novel signal processing architectures based on logarithmic arithmetic.

Careers

The programme targets producing engineers with the knowledge and skills required for working in the communications industry on programmable hardware, in particular. There is a high demand for people to fill such roles in communications and test & measure equipment vendors, and in many smaller companies developing devices for the internet of things.

Kent has an excellent record for postgraduate employment: over 94% of our postgraduate students who graduated in 2013 found a job or further study opportunity within six months.

We have developed our programmes with a number of industrial organisations, which means that successful students are in a strong position to build a long-term career in this important discipline. You develop the skills and capabilities that employers are looking for, including problem solving, independent thought, report-writing, time management, leadership skills, team-working and good communication.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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The School of Engineering and Digital Arts offers research-led degrees in a wide range of research disciplines, related to Electronic, Control and Information Engineering, in a highly stimulating academic environment. Read more
The School of Engineering and Digital Arts offers research-led degrees in a wide range of research disciplines, related to Electronic, Control and Information Engineering, in a highly stimulating academic environment. The School enjoys an international reputation for its work and prides itself in allowing students the freedom to realise their maximum potential.

Established over 40 years ago, the School has developed a top-quality teaching and research base, receiving excellent ratings in both research and teaching assessments.

We undertake high-quality research that has had significant national and international impact, and our spread of expertise allows us to respond rapidly to new developments. Our 30 academic staff and over 130 postgraduate students and research staff provide an ideal focus to effectively support a high level of research activity. There is a thriving student population studying for postgraduate degrees in a friendly and supportive teaching and research environment.

We have research funding from the Research Councils UK, European research programmes, a number of industrial and commercial companies and government agencies including the Ministry of Defence. Our Electronic Systems Design Centre and Digital Media Hub provide training and consultancy for a wide range of companies. Many of our research projects are collaborative, and we have well-developed links with institutions worldwide.

Visit the website https://www.kent.ac.uk/courses/postgraduate/262/electronic-engineering

Project opportunities

Some projects available for postgraduate research degrees (http://www.eda.kent.ac.uk/postgraduate/projects_funding/pgr_projects.aspx).

Research areas

- Communications

The Group’s activities cover system and component technologies from microwave to terahertz frequencies. These include photonics, antennae and wireless components for a broad range of communication systems. The Group has extensive software research tools together with antenna anechoic chambers, network and spectrum analysers to millimetre wave frequencies and optical signal generation, processing and measurement facilities. Current research themes include:

- photonic components
- networks/wireless systems
- microwave and millimetre-wave systems
- antenna systems
- radio-over-fibre systems
- electromagnetic bandgaps and metamaterials
- frequency selective surfaces.

- Intelligent Interactions:

The Intelligent Interactions group has interests in all aspects of information engineering and human-machine interactions. It was formed in 2014 by the merger of the Image and Information Research Group and the Digital Media Research Group.

The group has an international reputation for its work in a number of key application areas. These include: image processing and vision, pattern recognition, interaction design, social, ubiquitous and mobile computing with a range of applications in security and biometrics, healthcare, e-learning, computer games, digital film and animation.

- Social and Affective Computing
- Assistive Robotics and Human-Robot Interaction
- Brain-Computer Interfaces
- Mobile, Ubiquitous and Pervasive Computing
- Sensor Networks and Data Analytics
- Biometric and Forensic Technologies
- Behaviour Models for Security
- Distributed Systems Security (Cloud Computing, Internet of Things)
- Advanced Pattern Recognition (medical imaging, document and handwriting recognition, animal biometrics)
- Computer Animation, Game Design and Game Technologies
- Virtual and Augmented Reality
- Digital Arts, Virtual Narratives.

- Instrumentation, Control and Embedded Systems:

The Instrumentation, Control and Embedded Systems Research Group comprises a mixture of highly experienced, young and vibrant academics working in three complementary research themes – embedded systems, instrumentation and control. The Group has established a major reputation in recent years for solving challenging scientific and technical problems across a range of industrial sectors, and has strong links with many European countries through EU-funded research programmes. The Group also has a history of industrial collaboration in the UK through Knowledge Transfer Partnerships.

The Group’s main expertise lies primarily in image processing, signal processing, embedded systems, optical sensors, neural networks, and systems on chip and advanced control. It is currently working in the following areas:

- monitoring and characterisation of combustion flames
- flow measurement of particulate solids
- medical instrumentation
- control of autonomous vehicles
- control of time-delay systems
- high-speed architectures for real-time image processing
- novel signal processing architectures based on logarithmic arithmetic.

Careers

We have developed our programmes with a number of industrial organisations, which means that successful students are in a strong position to build a long-term career in this important discipline. You develop the skills and capabilities that employers are looking for, including problem solving, independent thought, report-writing, time management, leadership skills, team-working and good communication.

Kent has an excellent record for postgraduate employment: over 94% of our postgraduate students who graduated in 2013 found a job or further study opportunity within six months.

Building on Kent’s success as the region’s leading institution for student employability, we offer many opportunities for you to gain worthwhile experience and develop the specific skills and aptitudes that employers value.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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This MSc programme targets the needs of a rapidly evolving telecommunications sector and provides an industrially relevant and exciting qualification in the latest broadband and mobile technologies being employed and developed. Read more
This MSc programme targets the needs of a rapidly evolving telecommunications sector and provides an industrially relevant and exciting qualification in the latest broadband and mobile technologies being employed and developed.

Study the techniques and technologies that enable broadband provision through fixed and wireless/mobile networks, and that modernise the core networks to provide ultra-high bit-rates and multi-service support. The Broadband and Mobile Communication Networks MSc at Kent is well-supported by companies and research establishments in the UK and overseas.

The programme reflects the latest issues and developments in the telecommunications industry, delivering high-quality systems level education and training. Gain deep knowledge of next-generation wireless communication systems including antenna technology, components and systems, and fibre optic and converged access networks.

Visit the website https://www.kent.ac.uk/courses/postgraduate/247/broadband-mobile-communication-networks

About the School of Engineering and Digital Arts

The School of Engineering and Digital Arts (http://www.eda.kent.ac.uk/) successfully combines modern engineering and technology with the exciting field of digital media. The School was established over 40 years ago and has developed a top-quality teaching and research base, receiving excellent ratings in both research and teaching assessments.

The School undertakes high-quality research that has had significant national and international impact, and our expertise allows us to respond rapidly to new developments. Our 30 academic staff and over 130 postgraduate students and research staff provide an ideal focus to effectively support a high level of research activity. We have a thriving student population studying for postgraduate degrees in a friendly and supportive teaching and research environment.

We have research funding from the Research Councils UK, European research programmes, industrial and commercial companies and government agencies including the Ministry of Defence. Our Electronic Systems Design Centre and Digital Media Hub provide training and consultancy for a wide range of companies. Many of our research projects are collaborative, and we have well-developed links with institutions worldwide.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

EL872 - Wireless/Mobile Communications (15 credits)
EL873 - Broadband Networks (15 credits)
EL822 - Communication Networks (15 credits)
EL827 - Signal & Communication Theory II (15 credits)
EL849 - Research Methods & Project Design (30 credits)
EL871 - Digital Signal Processing (DSP) (15 credits)
EL891 - System and Circuit Design (15 credits)
EL892 - Satellite and Optical Communication Systems (15 credits)
EL890 - MSc Project (60 credits)

Assessment

The project module is examined by a presentation and dissertation. The Research Methods and Project Design module is examined by several components of continuous assessment. The other modules are assessed by examinations and smaller components of continuous assessment. MSc students must gain credit from all the modules. For the PDip, you must gain at least 120 credits in total, and pass certain modules to meet the learning outcomes of the PDip programme.

Programme aims

This programme aims to:

- educate graduate engineers and equip them with advanced knowledge of telecommunications and communication networks (including mobile systems), informed by insights and problems at the forefront of these fields of study, for careers in research and development in industry or academia

- produce high-calibre engineers with experience in specialist and complex problem-solving skills and techniques needed for the interpretation of knowledge and for systems level design in the telecommunications field

- provide you with proper academic guidance and welfare support

- create an atmosphere of co-operation and partnership between staff and students, and offer you an environment where you can develop your potential

- strengthen and expand opportunities for industrial collaboration with the School of Engineering and Digital Arts.

Research areas

- Communications

The Group’s activities cover system and component technologies from microwave to terahertz frequencies. These include photonics, antennae and wireless components for a broad range of communication systems. The Group has extensive software research tools together with antenna anechoic chambers, network and spectrum analysers to millimetre wave frequencies and optical signal generation, processing and measurement facilities.

Current main research themes include:

- photonic components
- networks/wireless systems
- microwave and millimetre-wave systems
- antenna systems
- radio-over-fibre systems
- electromagnetic bandgaps and metamaterials
- frequency selective surfaces.

Careers

We have developed the programme with a number of industrial organisations, which means that successful students will be in a strong position to build a long-term career in this important discipline.

School of Engineering and Digital Arts has an excellent record of student employability. We are committed to enhancing the employability of all our students, to equip you with the skills and knowledge to succeed in a competitive, fast-moving, knowledge-based economy.

Graduates who can show that they have developed transferable skills and valuable experience are better prepared to start their careers and are more attractive to potential employers. Within the School of Engineering and Digital Arts, you can develop the skills and capabilities that employers are looking for. These include problem solving, independent thought, report-writing, time management, leadership skills, team-working and good communication.

Building on Kent’s success as the region’s leading institution for student employability, we offer many opportunities for you to gain worthwhile experience and develop the specific skills and aptitudes that employers value.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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In an increasingly overcrowded electromagnetic spectrum, the efficient and reliable operation of wireless, mobile and satellite communication systems, and of radar and remote sensing systems, relies upon advanced components and subsystems that exploit ongoing developments in technologies such as microfabrication, nanotechnology and high frequency semiconductor devices. Read more
In an increasingly overcrowded electromagnetic spectrum, the efficient and reliable operation of wireless, mobile and satellite communication systems, and of radar and remote sensing systems, relies upon advanced components and subsystems that exploit ongoing developments in technologies such as microfabrication, nanotechnology and high frequency semiconductor devices.

This programme provides training for engineers to become innovators in these rapidly expanding markets. A firm grasp of the fundamentals is established through modules in the foundations of communications engineering and in satellite, cellular and optical fibrte communications, electromagnetics and antennas, propagation, radio frequency and microwave engineering and computer and communications networksprovide advanced knowledge in an aspect of the relevant component technologies.

The programme will help you to develop an ability to interpret user requirements and component specifications, to engineer effective designs within the constraints imposed by the available resources and the fundamental physical limits. The programme provides a theoretical basis from which the design, construction and operation of satellite and cellular radio communications can be understood.

About the School of Electronic, Electrical & Systems Engineering

Electronic, Electrical and Systems Engineering, is an exceptionally broad subject. It sits between Mathematics, Physics, Computer Science, Psychology, Materials Science, Education, Biological and Medical Sciences, with interfaces to many other areas of engineering such as transportation systems, renewable energy systems and the built environment.
Our students study in modern, purpose built and up to date facilities in the Gisbert Kapp building, which houses dedicated state-of-theart teaching and research facilities. The Department has a strong commitment to interdisciplinary research and boasts an annual research fund of more than £4 million a year. This means that wherever your interest lies, you can be sure you’ll be taught by experts in the field.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/pgfunding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/pgopendays

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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This course aims to provide you with key, advanced level knowledge and skills that will allow you to succeed in the rapidly growing wireless and microwave communication industry. Read more
This course aims to provide you with key, advanced level knowledge and skills that will allow you to succeed in the rapidly growing wireless and microwave communication industry. You will also develop research skills and other related abilities, enhancing your general engineering competency, employability, and providing you with an excellent platform for career development, whether that be within industry or academic research.

In addition, modules delivered by Cardiff University’s internationally recognised Business School will allow you the opportunity to gain valuable skills in entrepreneurship and an insight into what’s involved in starting your own business.

More specifically, the programme aims to equip you with:

Expertise in new and evolving areas, such as advanced microwave computer aided design and communication systems engineering.
Laboratory time and advanced engineering management alongside modules in radio frequency engineering, advanced industry standard microwave computer aided design (CAD) tools, fabrication and testing, advanced communication systems, advanced communication networks and non-linear RF designs and concepts.
Skills in entrepreneurship across a variety of business and technology disciplines complemented by the specialist modules taught by Cardiff Business School.
Real world technology product development experience, learn best practices and build an exceptional network from seasoned and successful entrepreneurs.
If you have software skills, you will have the opportunity to apply to the Alacrity Foundation to take part in their “boot camp”. This 12 month programme provides graduates with practical business training, software skills & mentorship so they can develop as entrepreneurs and launch their own UK based technology companies.

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The Renewable Energy and Clean Technology (REaCT) course focuses on the key areas which underpin the rapidly developing renewable energy and low carbon sectors. Read more
The Renewable Energy and Clean Technology (REaCT) course focuses on the key areas which underpin the rapidly developing renewable energy and low carbon sectors. It will give you the skills and knowledge required to contribute to the design, development and planning of clean energy infrastructure - probably the greatest engineering goal of the 21st century.

The course is built around a core understanding of electrical power generation from solar, wind and marine sources and covers the interfacing and distribution technologies needed to exploit these sources. Equally, the impact of renewable energy will be diminished if demand and carbon emission are not reduced, these topics are key to the course.

This multidisciplinary course is geared towards teaching the skills needed by employers in a sector which is set to expand as fossil fuels decline and carbon emission is reduced. It will equip you with the tools required for research into future energy sources and low carbon technologies.

The REaCT course will give our graduates the depth and breadth of training which will prepare them to become involved in this technology revolution either by joining the renewable industry or by undertaking further research studies as part of a University of Manchester PhD programme.

This course delivers up-to-date topics on communications and microwave engineering. It covers wide-ranging and in-depth materials including digital communication, wireless communications, mobile networks, optical communications, adhoc networks, information theory, antenna design, microwave systems and circuit design and digital signal processing.

The programme is aimed at those with some previous undergraduate knowledge of communication and radio frequency engineering topics, wishing to enhance their skills to an advanced level compatible with a career in these industries. It also serves as an excellent introduction and training for further research leading to the degree of PhD.

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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 programme will not have a 2016 intake as the content is being extensively improved. Microcontrollers are being designed into more and more products e.g. Read more

NOTE

This programme will not have a 2016 intake as the content is being extensively improved.

Overview

Microcontrollers are being designed into more and more products e.g. motor cars, washing machines, mobile phones etc. The fast growing and challenging area of embedded systems requires engineers with hardware and software design capabilities for use in this variety of situations. This advanced programme of study offers a natural progression route for graduates in electrical and electronic engineering, physics, computer science, or related disciplines, and is structured to provide the student with the necessary skills for embedded systems development.

Aims and Objectives

To provide knowledge of electronic systems design based around microcontrollers
To provide the ability to manage new technologies and integrate them into system design
To satisfy the growing demand for engineers with embedded systems experience
To facilitate professional development of the student that will lead to a successful professional career

Distinctive features

MSc in Embedded Systems is for students who wish to study a programme to engage them in system development and design focussing on microcontrollers, both hardware and software. It will provide advanced knowledge in areas essential for this type of design and development, whilst also providing learning in areas closely associated to embedded systems such as control and communications.

Modular structure

The course conforms to the standard University of Hull structure, consisting of two taught semesters (the Diploma stage) followed by a substantial individual project. Core modules are compulsory; choice of optional modules is based on student preferences.

Core:

Advanced Digital Systems Design (Semester 1)
Product Planning and Design Exercise (Semester 1)
Complex Circuits and Systems (Semester 2)
Advanced Discreet Time Signal Processing and Integrated Circuit Design (Semesters 1 and 2)
Dissertation project

Options:

Mobile Radio
Propagation and Antennas
Advanced Control
Radio Frequency and Microwave Devices
Techniques and Measurements
Machine Vision

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