Electrical and Electronic Engineering
with a Year in Industry
Building a future with sustainable engineering strategies
Building a future with sustainable engineering strategies
Electrical and electronic engineering touches on almost every aspect of modern life, and with sustainability so important for the world right now, there’s never been a better time to study this area.
From renewable energy generation to smart power distribution and the development of low powered embedded devices, Kent will provide you with the specialist knowledge and broad skills in both disciplines; making you career ready for the future direction of engineering.
The fourth year of this MEng qualification brings your engineering skills up to an advanced level. You'll develop in areas like energy storage technology, advanced electronic storage and power network management.
Gain engineering experience working in a professional environment and develop employment-related skills. The placement year develops your technical skills, employability, and soft skills as well as increasing your awareness of the future context for employment.
We have excellent industrial links, providing you with many placement opportunities.
The MEng brings your engineering skills to an advanced level.
First-class facilities to support your development with access to computer and engineering labs, mechanical workshop, dedicated makerspaces and more.
With tech rapidly advancing, there's a higher global demand for professional electrical and electronic engineers more than ever before.
You’ll study exciting subjects like power electronics, renewable energy technology, robotics and systems programming.
Our typical offer levels are listed below and include indicative contextual offers. If you hold alternative qualifications just get in touch and we'll be glad to discuss these with you.
ABB including B in Mathematics plus one other STEM subject.
DMM in an Engineering subject including Further Maths/Further Maths for Engineering Technicians/Calculus to Solve Engineering Problems. Other subjects are considered on a case-by-case basis. Please contact us for further advice on your individual circumstances.
120 tariff points from your IB Diploma, including Maths (not Maths Studies) at 5 at HL or 6 at SL, or Maths: Analysis and Approaches at 5 at HL or 6 at SL, or Maths: Applications and Interpretations at 5 at HL or 6 at SL, and a science subject at 5 at HL or 6 at SL, typically H5, H6, H6 or equivalent.
N/A
The University will consider applicants holding T level qualifications in subjects closely aligned to the course.
A typical offer would be to obtain the Access to HE Diploma in a suitable subject with a minimum of 45 credits at Level 3, with 24 credits at Distinction and 21 credits at Merit.
The following modules are what students typically study, but this may change year to year in response to new developments and innovations.
Mathematics is the fundamental language of engineering, allowing complex ideas to be described, formulated and developed. This module gives you a strong foundation of key mathematical techniques and methods required by most other modules in our engineering courses.
Topics covered include complex numbers, calculus, linear algebra, statistics and probability. Throughout the module, you’ll tackle real-world engineering problems. These include the study of mechanical and electrical systems, the use of complex numbers and linear algebra for the analysis of electrical circuits and the use of statistics and probability in the analysis of experimental data.
Electronics underpins all of modern life, from everyday household items to the most sophisticated supercomputers. It enables devices such as ultra-low power wearable health monitors through to megawatt wind turbines.
You’ll begin your engineering journey by learning fundamental circuit analysis and fabrication skills. This will enable you to begin engineering project work right from your first year.
You’ll also explore the vital and trusted role that engineers play in supporting and transforming society and infrastructure. You’ll do this by demonstrating your ability to consider societal issues essential to modern professional engineering.
Programming underpins all facets of modern life, from basic software applications to complex artificial intelligence systems. It enables everything from simple mobile apps to large-scale enterprise solutions.
You'll embark on your programming journey here, mastering fundamental coding concepts and development skills. This foundation will empower you to dive into programming projects right from your first year through lectures, workshops and programming challenges.
You’ll also examine the pivotal role of programmers in shaping and advancing society by exploring ethical and societal considerations essential to contemporary professional programming.
The success of an engineering product relies on the combination of careful mechanical design, strategic material selection, and a deep understanding of mechanics. These elements collectively shape the product's performance, durability, and overall effectiveness, highlighting their essential role in the development of any successful engineering solution.
You'll learn how to develop an engineering drawing of a product using a Computer-Aided Design (CAD) system and choose the best materials from a wide range of available engineering materials for your designed components.
This material selection process depends on the mechanical analysis of a component under various loading scenarios, which you will learn in this module. This knowledge will enable you to start developing an engineering project from your first year of study and practise it throughout your degree.
To bring your engineering education to life, you’ll do a project in each year of study. In the Stage 1 project, you'll gain hands-on experience, allowing you to apply theoretical knowledge to real-world problems. It will enhance your understanding of engineering principles and concepts.
Throughout this process, you’ll apply electronic and mechanical design skills and programming/software knowledge to describe and produce a physical solution alongside a technical specification. You are expected to gain a foundational understanding of engineering hardware and software integration and verification.
The module progresses through lectures, workshops, and labs, tutorials with supervision and technical guidance. It aims to provide you with hands-on and problem-solving skills in the concepts elucidated in the Term 1 and Term 2 modules.
Electronic Engineers need a knowledge of both analogue and digital electronic circuits and electronic devices to effectively design future products.
This module introduces you to analysis and design techniques and electronic component properties. You’ll learn using circuit analysis software, commonly used in industry and practical work using industrial standard measurement equipment.
Engineers work in interdisciplinary teams to overcome the challenges of intelligent engineering systems. Smart engineering systems are not simple mechanical or electronic components, but the result of synergistic integration between mechanical engineering, electronics, computer science and control.
You’ll learn to apply this interdisciplinary approach to develop innovative solutions that would not be possible with a single-discipline focus. You’ll gain applied knowledge of sensors, actuators, and data acquisition techniques which are crucial to modern engineering. After mastering the foundational concepts, you’ll progress to cover transducers, mechanical components and modelling of mechatronic systems.
You’ll further explore microprocessors and data acquisition processes and become familiar with actuator functions within mechatronic systems. Practical sessions will complement your theoretical learning, allowing you to apply concepts in hands-on scenarios with real-world systems.
Microcomputer technology is widely used in the design and development of modern computer systems. Many of us use such applications every day, in devices such as smartphones, washing machines, microwaves and cars.
In this module, you’ll learn general principles of computer architecture and understand how the microprocessor executes instructions, interacts with hardware components and communicates with memory and I/O devices. The most common microprocessors and microcontrollers will be to compare their architectures and processing resources.
You’ll also learn a programming language that can be used on a number of microcontrollers and discover how to program and compile on a given microcontroller through a series of practical sessions. As part of a mini-project, you’ll then design and develop a microcontroller-based system using its I/O features and different communication protocols (such as RS232, SPI and I2C).
Power electronics is the study and application of electronic devices and circuits for efficient control and conversion of electrical power. This module gives you an overview of the fundamental principles of power electronic devices and their applications in various electrical systems.
First, we’ll introduce you to power semiconductor devices, including power diodes, thyristors, and insulated gate bipolar transistors (IGBTs), uncovering their unique characteristics and operational intricacies. This will then lead to rectifier circuits such as half-wave and full-wave rectifiers converting AC to DC power as well as exploring the intricacies of Buck, Boost, and Buck-Boost converters, and their role in transforming DC power.
You will then unravel the mysteries of inverter circuits for DC-AC conversion. Finally, you’ll explore the diverse landscape of power supplies, from linear to switch-mode designs, giving you insight into their design principles and practical implementation.
Power electronics forms the backbone of modern electrical systems, including renewable energy systems, electric vehicles, consumer electronics, industrial automation, and many more. Understanding power electronics will provide a strong foundation for working with these advanced technologies.
What are the principles and applications of various electrical machines that are commonly used in engineering and industrial settings?
Through theoretical lectures, workshops, and hands-on laboratory sessions, you’ll delve into the fundamental concepts underlying the functioning of electrical machines. These include motors, generators, and transformers, and you’ll also gain the knowledge and skills necessary to analyse, design, and optimise electrical machines for diverse engineering applications.
This will prepare you for careers in electrical engineering, power systems, renewable energy and related fields.
You spend a year working in industry between Stages 2 and 3. You gain practical work experience, while assessing possible future career options and making contacts in the industry. Employers are always keen to employ graduates with knowledge of the work environment and some students receive job offers from their placement company.
We have a dedicated Employability Officer who will help you apply for placements; but please note that it is your responsibility to secure a placement, which cannot always be guaranteed. The School has excellent industrial links, providing students with many placement opportunities.
Industrial Placement Experience
Industrial Placement Report
This is an opportunity for independent study on a topic of your own choice. Working on the project is a major part of your final year of study, taking place in spring and summer terms. It’s a chance for you to conduct in-depth research on a subject that is relevant to your course, helping you to further develop essential skills.
It will also challenge you to solve problems which involve the critical consideration of engineering and relevant legal, social, ethical and professional issues. It will enable you to develop and practise a professional approach to delivering written and oral presentations. You will be allocated a supervisor who will support you through weekly meetings and other communications.
To help you build the required knowledge and skills you’ll need for a successful engineering project, you’ll attend a series of lectures and workshops. These will cover topics such as design and production techniques; reliability, availability, maintainability and safety (RAMS), quality, safety and electromagnetic compatibility (EMC); as well as ethical, environmental and EDI (equality, diversity and inclusion) issues.
Programmable logic devices are an essential element of modern digital design. Unlike a microcontroller that is software programmable (but otherwise comprises a fixed set of hardware resources), programmable logic devices such as Field-Programmable Gate Arrays (FPGAs) entail re-programming of the hardware itself. As such they allow fast prototyping and flexibility in the hardware design of modern digital systems (ranging from telecoms to control systems) due to their ability to be reprogrammed in the field.
In this module, you'll learn to program in a hardware-description language (VHDL) to model and simulate digital electronic circuits. Through a series of practical sessions, you will learn the necessary electronic design automation tools and how they are used to compile and simulate VHDL code but also “synthesise” VHDL code for placement onto actual physical hardware. You'll also learn the fundamental operational principles of programmable logic devices, FPGAs and their main processing elements, and also how modern FPGAs are used to build system-on-chips (SoCs). You will be introduced to the concepts of boundary scan testing and learn about the JTAG protocol (IEEE standard 1149.1). You'll apply knowledge gained in mini projects that will involve designing complete digital systems implemented onto FPGA, deepening your understanding and building your experience.
Want to learn the fundamentals of how power systems create and distribute energy? This module covers the concept of power generation and transmission using interconnected grid systems, overhead and underground power transmission and distribution systems.
You’ll learn the fundamentals of designing, operating, and analysing modern electrical power transmission and distribution networks. You’ll do this by concentrating on models and techniques used to describe and analyse the behaviour of such systems as well as the specification of major equipment used in such systems. You’ll then consider the stability of power grids and identify the techniques for their protection.
What sources of renewable energy are there? How are technological developments improving electrical generation and meeting the global rise in demand for clean energy?
After exploring the impact of fossil fuels on our environment, you’ll get an overview of various renewable energy sources and their associated challenges and opportunities. We’ll then focus on some major sources – like solar energy and wind power technologies – in more detail.
You’ll also briefly look at other renewable energy sources such as wave and tidal, hydropower and geothermal and get a brief overview of energy storage. By the end of the module, you’ll have a strong sense of which technologies are being proposed to meet the world's growing demand for green energy.
Image analysis techniques give computers the power to enhance, interpret and understand visual inputs. These techniques are integral to many applications such as autonomous vehicles, medical diagnosis, document processing, biometric security and surveillance.
You’ll learn the principles of image analysis techniques alongside their practical applications. Starting from basic image formation and acquisition, you’ll learn core image processing techniques such as how to filter noise, how to extract object outlines, how to identify regions of interest in an image (segmentation), and about image feature descriptors.
You’ll also explore various supervised and unsupervised classification techniques (including neural networks) for object recognition. You’ll discover several real-world applications of image analysis and learn through lab-based exercises and a mini-project.
Embedded systems in conjunction with the Internet of Things (IoT) are used to create systems that can sense in real-time different aspects of their environment, collect and transmit information for a vast number of applications including smart cities, smart agriculture and smart factories (Industry 4.0). This information can then be used to transform the day-to-day operation of our cities and businesses making them more efficient and less wasteful of resources.
This module introduces the theory and practice of employing computers as the control and organisational centre of embedded systems and examines time-critical systems. You'll also cover design aspects of embedded systems and IoT through practical work, including real-time operating systems and microcomputer programming.
You will learn how to use the internal peripherals of a microcontroller by working directly at the hardware register level and as such gain a good understanding of the interactions between software and hardware. Many practical applications of embedded systems require real-time operation under strict deadlines (e.g., in factory automation). As such, the module also covers the concepts of real-time operating systems and features that are essential for time-critical operation. IoT can be used as the backbone communication infrastructure in embedded applications and the skills and knowledge you develop will be crucial in your future career.
In today's interconnected world, cyber security is not just important – it is essential. From businesses to schools, homes, personal devices, and even vehicles, everything is connected! This module dives deep into the fascinating realm where cyber security – including general topics and specialist areas such as cryptography – take centre stage.
Get ready to explore how these fields shape the modern technology landscape, from fundamental security principles to the intricate dance between risk management, cybercrime, usable security and professional aspects. You'll unravel the mysteries of ciphers, delve into the world of symmetric and asymmetric cryptography, and even take a critical look at cyber-attacks. You'll also examine their social and technical dimensions and explore effective risk treatment measures. This includes robust security controls and the use of upcoming mechanisms such as cyber insurance.
The knowledge you will gain on this module provides a strong foundation to guide and inform security efforts within an organisation. Prepare to embark on a journey where every click, every byte, and every line of code matters – and where you knowledge can make a real difference.
Building on the material from Stage 1, in this module you will delve further into electronic engineering topics covering the principles and operation of essential electronic components and systems. You will learn about different passive and active electronic components (e.g., passive and active filters) focusing on both theoretical and practical aspects pertaining to the design of modern analogue and digital systems including frequency response characteristics, power-consumption and noise. You will learn about modern digital Integrated Circuit (IC) design at the circuit, chip/silicon and board level, through an introduction to the metal-oxide-semiconductor field-effect transistor (MOSFET) and Complementary MOS (CMOS) logic. You will also learn the principles of microwave technology, including the design of microwave filters and transmission lines. The module proceeds via a sequence of lectures supported by example classes, exercises and workshops designed to give practical experience of the concepts introduced in the lectures.
This is an opportunity for collaborative study on a topic collectively chosen by the group members. It constitutes a significant portion of final year of the MEng, taking place in the Spring and Summer Terms. The main aim is to delve deeply into a relevant subject while honing transferable key skills that are crucial for professional development.
Through this project, you'll encounter and address engineering challenges while critically examining legal, social, ethical, and professional considerations. You’ll also develop your written and oral presentation skills in a professional context. Each group will be assigned a supervisory team who will provide regular guidance, ensuring a cohesive and productive project. This collaborative endeavour aims to foster a professional environment where you can collectively research, problem-solve, and grow as an engineer.
To help you build the necessary knowledge and skills for developing a systems engineering project, you’ll learn through a series of lectures, seminars and workshops covering topics including project management, commercial and industrial considerations, and other factors and associated risks. You’ll also address ethical and environmental issues relevant to systems engineering, ensuring a holistic understanding of the project development process.
The Industrial Internet of Things (IIoT) enables real-time monitoring, predictive maintenance and data-driven decision-making to enhance efficiency, productivity, and competitiveness across various industrial sectors. Additionally, IIoT facilitates the integration of advanced technologies such as sensing, connectivity, networking, and security, paving the way for smarter, more agile, and interconnected industrial systems.
In this module, you'll conduct an in-depth exploration of IIoT, focusing on key aspects such as sensing, connectivity, networking, security and applications. We cover the principles, technologies and methodologies required to design, implement, and manage IIoT systems in industrial settings. Through a combination of theoretical lectures, practical workshops, case studies, and hands-on projects, you’ll gain the knowledge and skills necessary to deploy robust and secure IIoT solutions across various industrial domains.
Power grid and energy storage technologies are critically essential to meet users’ demand for sustainable system as well as to provide cost effective security and quality supply.
In this module, you will be learning a comprehensive knowledge of advanced power grid technologies, focusing on modelling, analysis, operation, and storage integration. The module covers a wide aspect of electrical power systems, including generation, transmission, and distribution, with an emphasis on addressing contemporary challenges and implementing cutting-edge solutions. Essential concepts such as power flow and voltage control will be covered, alongside advanced topics like security-constrained optimal power flow, current & voltage protection, and the operation of power flow controllers. Additionally, concepts related to smart system issues will be studied through both software-based experiments and industrial tutorials.
Real-time embedded systems have widespread applications in modern life, including consumer electronics, automotive systems, medical devices and industrial control systems. This module gives you the skills to design, develop and maintain these embedded systems effectively, optimising performance, managing complexity, and ensuring reliability. You’ll also develop aptitudes to meet industry needs and prepare you for a successful career in embedded systems engineering.
You’ll study the theory and practice of embedded real-time operating systems (RTOS), RTOS software development tools and environments, concurrent programming, scheduling and synchronisation. You’ll explore the design aspects of real-time embedded systems through practical work, including RTOS, embedded systems programming and heterogeneous computing.
You’ll also learn hardware/software co-design considerations which are essential for modern system development. By integrating these considerations from the outset, you can create optimised real-time embedded systems that meet the demands of modern applications effectively and efficiently.
This module will cover the essentials of power system operation, analysis and governance from a systemic approach. After a generic overview of the interconnected grid network, you will learn load flow analysis techniques which facilitates efficient transmission of power to all load centres in a complex network. Fault analysis will then be covered along with appropriate protective mechanisms, which facilitates maintaining system stability. There will be an overview of the electricity market economics, regulatory & policy matters as well.
Most modules consist of a mixture of lectures, seminars, workshops and computer sessions. All modules are continuously assessed. All years include project work that replicates industrial practice to maximise the employability of our graduates.
For a student studying full time, each academic year of the programme will comprise 1200 learning hours which include both direct contact hours and private study hours. The precise breakdown of hours will be subject dependent and will vary according to modules.
Methods of assessment will vary according to subject specialism and individual modules.
Please refer to the individual module details under Course Structure.
For course aims and learning outcomes, please see the course specification.
You'll develop into a well-rounded graduate, confident of your future opportunities as we support you to recognise and learn the essential skills and attributes needed by industries in the UK and overseas.
This course has been designed in discussion with industrial employers, our Industrial Panel, IET, our graduates, and students. This allows the latest real-world developments and latest academic research to be included in the curriculum. Lecturers and guest speakers include those with industry experience and experience working with industry on research and commercial innovation. We use this industrial knowledge and our networks to support your development.
Accreditation will be sought from the Institution of IET enabling students to satisfy the partial educational requirements of the IET for Chartered Engineer (CEng) registration upon successful completion of the course.
The Careers and Employability Service supports you when looking for graduate employment, placements, work experience, internships, and volunteering. They help you to identify career paths, and support you through applications, interviews and assessment centres. They also provide a programme of events, giving you industry insight and an opportunity to network.
The 2025-26 annual tuition fees for UK undergraduate courses have not yet been set by the Department for Education.
For details of when and how to pay fees and charges, please see our Student Finance Guide.
For students continuing on this programme, fees will increase year on year by no more than RPI + 3% in each academic year of study except where regulated.*
The University will assess your fee status as part of the application process. If you are uncertain about your fee status you may wish to seek advice from UKCISA before applying.
Fees for undergraduate students are £1,850.
Fees for undergraduate students are £1,385.
Students studying abroad for less than one academic year will pay full fees according to their fee status.
Students will require regular access to a desktop computer/laptop with an internet connection to use the University of Kent’s online resources and systems. Please see information about the minimum computer requirements for study.
There may be additional costs associated with the Year in Industry such as travel or accommodation, which will need to be covered by the student. Please see Careers and Employability webpages for more information.
Find out more about accommodation and living costs, plus general additional costs that you may pay when studying at Kent.
Kent offers generous financial support schemes to assist eligible undergraduate students during their studies. See our funding page for more details.
You may be eligible for government finance to help pay for the costs of studying. See the Government's student finance website.
Scholarships are available for excellence in academic performance, sport and music and are awarded on merit. For further information on the range of awards available and to make an application see our scholarships website.
We have a range of subject-specific awards and scholarships for academic, sporting and musical achievement.
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