Triangle

Course overview

Electrical engineers design and develop new technologies to generate and process power. The equipment they design is used to distribute electrical energy (including 'Smart Grid' technologies for renewable energy sources), and also supports many manufacturing industries.

Electrical engineering technologies now enable hybrid and electric vehicles, trains, ships and
even aircraft.

Our course will give you the specialist electrical knowledge and skills that will help you be part of a more sustainable future. Through lab-based projects, working individually and in small teams, you'll learn essential problem solving and design skills.

During your second year, you can study at either our China or Malaysia campus where you will have the opportunity to experience differing cultures. The curriculum is exactly the same as that of the UK and all teaching is in English. Your year will be spent studying core modules, and depending on the subject specialisms you have selected, appropriate optional modules.

By bringing together your numerical, analytical and technical knowledge, you will be confident in creating engineering solutions that industry are looking for.

All our electrical and electronic courses have the same content in year one and two so by year three, you can choose to specialise in the topics that interest you.

 

Why choose this course?

Top 15

in the UK for electrical and electronic engineering

The Guardian University Guide, 2022

Practical

lab-based sessions to help you develop skills for your future career

Customise your degree

to suit your interests with a wide selection of optional modules


Entry requirements

All candidates are considered on an individual basis and we accept a broad range of qualifications. The entrance requirements below apply to 2022 entry.

UK entry requirements
A level AAA-ABB
Required subjects

AAA-ABB. Required subjects: Maths and either electronics or a science subject (computer science, physics, chemistry or biology). Citizenship studies, critical thinking and general studies are not accepted.

IB score 36-32 Including Mathematics: Analysis and Approaches = 5/6 at Higher Level or 6/7 at Standard Level, and Mathematics: Applications and Interpretation = 5/6 at Higher Level only. And 5/6 at Higher Level in one of biology, chemistry or physics.

BTEC/Access/HND qualifications are considered on an individual basis. 

Foundation progression options

A foundation year is available for those with BBB grades but not in the required subjects.

Learning and assessment

How you will learn

Teaching methods

  • Group study
  • Independent study
  • Lab sessions
  • Lectures
  • Practical classes
  • Supervision
  • Tutorials
  • Workshops

How you will be assessed

Assessment methods

  • Coursework
  • Dissertation
  • Examinations
  • Group coursework
  • Practical exams
  • Presentation
  • Research project
  • Practical assessment

Contact time and study hours

On average, you will have around 20 contact hours a week in year one and two. Combined with coursework and self-study, you may spend over 40 hours a week on your studies.

Study abroad

Engineering programmes and content of study are the same across our international campuses but there may be minor differences in the number of elective modules offered by some.

Post study abroad: students are supported to enable them to fully integrate back into their studies including co-ordinating module choices and projects as appropriate for their programme.

Modules

This year is common to all courses in the Electrical and Electronic Engineering department. Giving you the flexibility to change course at the end of the year. You will gain an understanding of the principles and practices on which all specialisms within electrical and electronic engineering are founded.

Core

Applied Electrical and Electronic Engineering Construction Project

In this module, you will be involved in the development of an autonomous vehicle building on knowledge learned in other parts of the course.

The work will be lab-based and undertaken in project weeks giving you a break from lectures in each semester.

You will work on this module for a third of the year.

Computer Aided Engineering

In this module you will start to develop one of the key skills for an engineer – that of being able to program. You will gain the skills required to analyse, design and implement solutions to practical engineering problems through the use of computer aided design tools and the development of software based solutions.

Engineering Mathematics 1

This module introduces you to the algebra of complex numbers. It provides a key mathematical tool for analysis of linear mathematical and engineering problems.

You will study the complexity of solving general systems of equations using matrix techniques and review the calculus of a single variable.

You will have a three hour lecture and workshops each week.

 

Information Systems

This module will introduce you to electronic systems and information.

You will begin by looking at:

  • signals
  • analogue/digital systems
  • electronic devices and communications systems

Teaching will use a 'top down' approach so you start with the big picture and work towards the more detailed view.

Power and Energy

Our world relies on reliable and secure electricity supplies, this module will introduce you to the  concepts and challenges faced in generating traditional and renewable electrical energy. 

The above is a sample of the typical modules we offer but is not intended to be construed and/or relied upon as a definitive list of the modules that will be available in any given year. Modules (including methods of assessment) may change or be updated, or modules may be cancelled, over the duration of the course due to a number of reasons such as curriculum developments or staffing changes. Please refer to the module catalogue for information on available modules. This content was last updated on Tuesday 14 September 2021.

During this year, you can study at either our China or Malaysia campus.Your year will be spent studying core modules, and depending on the subject specialisms you have selected, appropriate optional modules.

Your design skills will be developed through a variety of laboratory-based subjects.

Group projects, presentations and seminars enable you to gain the skills and understanding essential for the workplace.

Core

Contemporary Engineering Themes

Following on from year one, this module continues to introduce to a variety of themes that are at the forefront of contemporary electrical and electronic engineering systems. 

This provides a broader context for the material covered in the co-requisite modules. The topics covered will vary each year and typical subjects might include:

  • Smart Grids
  • Bio-sensing
  • Medical Electronics
  • Photonics
  • Electric Transportation
  • The Internet of Things
Electrical Energy Conditioning and Control

This module introduces you to the underpinning technologies for the conditioning, control and conversion of electrical energy.

The topics covered in this module include:

  • power electronics
  • control
  • electrical machines
  • renewable energy
Electronic Processing and Communications

In this module you will study:

  • intermediate level electronic analogue circuits and their use within more complex systems
  • digital design techniques
  • software tools
  • communications systems
  • sources and impact of noise and interference – a key topic for any electrical and electronic engineer
Modelling: Methods and Tools

Electrical and electronic engineers are often required to analyse and solve the problems they encounter. 

This module will teach you the required mathematical skills and suitable software tools needed for you to start modelling these problems yourself.

Some topics covered include:

  • analysis techniques for dynamic systems with application to communications and control theory
  • analysis techniques for digital systems and statistical analysis of signals and data
Practical Engineering Design Solutions and Project Development

This module partners with the lecture modules in the second year.

It gives you the chance to put your theoretical knowledge into practice through activities drawn from the design and development cycle.

You will be taking part in two, themed group projects:

  • power and energy 
  • electronics and communications 
The above is a sample of the typical modules we offer but is not intended to be construed and/or relied upon as a definitive list of the modules that will be available in any given year. Modules (including methods of assessment) may change or be updated, or modules may be cancelled, over the duration of the course due to a number of reasons such as curriculum developments or staffing changes. Please refer to the module catalogue for information on available modules. This content was last updated on

Choose from a range of specialist topics, with flexibility to maintain a broad base or focus on specific technologies.

Core

Advanced Engineering Mathematics (spring)

This module covers advanced analytic mathematical techniques used to provide exact or approximate solutions to common classes of ordinary differential equations (ODES) typical in Engineering.

Each week there will normally be one, one-hour lecture and a two-hour workshop to introduce key mathematical knowledge on module topics.

Techniques covered include:

  • method of variation of parameters
  • Laplace transform methods
  • Taylor series method
  • Frobenius method
  • asymptotic regular perturbations and strained coordinates
  • multiple scales

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Laboratory 5 weeks 1 week 2 hours
Lecture 11 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 25%  
Exam 75%  
Electrical Machines, Drive Systems and Applications (autumn)

This module introduces students to the concepts and operating principles of fixed and variable speed electric machine and drive systems.

The module will use a number of system examples to demonstrate how machines and drive systems are specified, designed, controlled and operated.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 week 2 hours
Practicum 11 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 25% 25 hours of student time
Exam 75% 2 hour exam
Group Project

This module is designed for you to build on your knowledge and put it into practice by being part of a group project. 

Power Electronic Applications and Control

Providing an understanding of the operational principles of power electronic converters and their associated systems, this module covers: 3-phase naturally commutated ac-dc/dc-ac converters, capacitive and inductive smoothing - device ratings, dc-ac PWM inverters and modulation strategies, resonant converters, high power factor utility interface circuits and power converter topologies for high power (multilevel). You’ll have two one-hour lectures per week.

Professional Studies

This module assesses your ability to develop a business plan based on an idea for a new product. This will give you the knowledge and skills needed for a graduate entering employment.

You will do this by learning various models, tools and concepts that are commonly used in business including:

  • Belbin’s model of team formation
  • the appropriate use of PEST and SWOT analysis
  • the basics of marketing
  • the product life cycle
  • technology audits
  • finance sources
  • intellectual property
  • ethics
  • product design

By the end of this module, you will be confident in:

  • writing and assessing rudimentary business plans
  • making informed decisions about product and business development

Optional

Analogue Electronics (autumn)

This module covers the design and analysis of electronic systems used in telecommunications particularly wireless devices.

You will look at devices including:

  • amplifiers
  • oscillators
  • phase-locked loops
  • mixers

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 7 weeks 2 weeks 2 hours
Lecture 4 weeks 1 week 2 hours
Practicum 4 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 50%
  • Investigation of design issues in single transistor amplifiers
  • submission of schematics
  • final report max 10 pages
Exam 50%
  • Two hour exam

 

Digital Communications (spring)

This module is an introduction to the operation of modern digital communication systems. Topics covered include:

  • communication systems
  • information content and channel capacity
  • digital modulation techniques
  • data compression techniques
  • error-correcting and line coding techniques
  • digital signal regeneration techniques
  • system examples, telephone, digital television and CD technologies.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 weeks 2 hours
Practicum 9 weeks 1 week 1 hour

Assessment method

Assessment Type Contribution  Requirements
Coursework 25% 12.5 hours of student time
Exam 75% 2 hour exam
Embedded Computing (spring)

This module aims to introduce principal generic and distinctive features of embedded computing, and develop practical skills in designing firmware for PIC16 microcontrollers using assembly language.

The modules includes:

  • Architectures for embedded programmable digital electronics
  • operation of a microcontroller and its programming
  • assembly language directives and instructions
  • interfacing of microcontrollers
  • embedded peripherals and interrupts in microcontrollers
  • communications for embedded computing
  • special features of microcontrollers (the above items are based on the PIC16 microcontroller family)
  • various microcontroller families
  • introduction to larger scale embedded systems

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 11 weeks 1 week 2 hours
Workshop 11 weeks 1 week 1 hour

Assessment method

Assessment Type Contribution  Requirements
Coursework 25% 12.5 hours of student time
Exam 75% 2 hour exam
Integrated Circuits and Systems

The module introduces CMOS integrated circuit design and internal operating mechanisms of semiconductor electronics and opto-electronic devices. 

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 2 weeks 2 hours
Practicum  11 weeks 1 week 2 hours

Assessment method

Assessment Type Weight
Coursework 50.00
Exam 50.00
IT Infrastructure and Cyber Security (autumn)

Providing you with the skills required to commission a complete IT system, this module provides information on network design and implementation, services, security and management of systems.

You’ll also be introduced to new uses of IT infrastructure (such as VoIP).

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 11 weeks 2 weeks 1 hour
Practicum 11 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution  Requirements
Coursework 75%  
Exam 25% 1 hour, multiple choice.
Mobile Technologies (spring)

This module provides knowledge of the fundamentals of mobile communications and its application to real systems.

Typical subjects might be 3rd and 4th generation systems, OFDM and MIMO and how 5th generation systems are likely to develop.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 week 2 hours
Practicum 3 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution  Requirements
Coursework 25% 12.5 hours of student time
Exam 75%  
Optical Networks (spring)

You will be introduced to the concepts and operating principles of optical communication systems and networks and the devices that underpin them.

Topics typically include:

  • characteristics of optical fibres
  • active and passive optical devices: including transmitters, detectors, amplifiers, multiplexers, filters and couplers

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution 
Coursework 25%
Exam 75%
Power Networks (spring)

This module provides students with an understanding of power system apparatus and their behaviour under normal and fault conditions. This module covers:

  • concept and analysis of load flow
  • voltage/current symmetrical components
  • computation of fault currents
  • economic optimisation
  • power-system control and stability
  • power system protection

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 11 weeks 1 week 2 hours
Practicum 11 weeks 1 week 1 hour

Assessment method

Assessment Type Contribution  Requirements
Coursework 25% 25 hours of student time
Exam 75% 2 hour exam
Renewable Generation Technologies (spring)

This module covers the analysis and design of renewable and sustainable energy systems. It covers the various types of renewable energy and the resources available.

It uses an understanding of the physical principles of various types of energy resources in order to develop analytical models which can be applied to the design of renewable energy systems, including energy conversion and storage, especially for electrical power generation.

It includes;

  • Wind power: wind probability distributions, wind turbine performance and control, comparison of generator types
  • Hydro and tidal power: resource assessment, turbine types and principles
  • Solar power, including PV cell equivalent circuit, analysis of losses, matching to DC and AC power systems
  • Wave power systems, including wave energy characteristics, types of energy converter
  • Characteristics of synchronous and induction generators
  • Embedded generation; types of generator and operation of RE within the power system
  • Economic and environmental assessment of energy conversion technologies.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 week 2 hours

 

Assessment method

Assessment Type Contribution  Requirements
Coursework 25% Sustainable energy case study: A written report.
Exam 75% Two Hour Paper. The examination will be based on the whole of the course.
Robotics, Dynamics and Control (spring)

This module is an introduction to electromechanical fundamentals in robotics and covers:

  • Direct kinematics
  • Inverse kinematics
  • Workspace analysis and and specifying appropriate robotic manipulators for industrial processes

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 week 2 hours
Lecture 12 weeks 1 week 1 hour

Assessment method

Assessment Type Contribution  Requirements
Coursework 25% 12.5 hours of student time
Exam 75% 2 hour exam
Scalable Cross-Platform Software Design (autumn)

Development and deployment of software for a variety of platforms ranging from the web and mobile devices through to large scale parallel computers.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 10 weeks 1 week 2 hours
Lecture 2 weeks 2 weeks 2 hours
Practicum 9 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution  Requirements
Coursework 1 25% 25 hours of student time
Coursework 2 25% 25 hours of student time
Coursework 3 25% 25 hours of student time
Exam 25% 1 hour, multiple choice
Sensing Systems and Signal Processing (spring)

This module covers a selection of topics where information is acquired from sensors and subsequently electronically processed.

Applications include:

  • optical
  • acoustic
  • non-destructive evaluation
  • medical
  • biophotonics

Method and Frequency of Class:

Activity Number of Weeks Number of sessions Duration of a session
Lecture 9 weeks 1 week 2 hours
Practicum 2 weeks 1 week 3 hours


Method of Assessment:

Assessment Type Contribution  Requirements
Coursework 50% Comprised of 3 pieces 
Exam 50%  
Systems Engineering (spring)

This module is to provide students with a good understanding of the concepts of systems engineering, including information on a range of relevant interdisciplinary material that electrical and electronic engineers would typically take into account, developing critical assessment skills through holistic lifecycle consideration.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 week 2 hours

Assessment method

Assessment Type Weight
Coursework  50.00
Exam 50.00
The above is a sample of the typical modules we offer but is not intended to be construed and/or relied upon as a definitive list of the modules that will be available in any given year. Modules (including methods of assessment) may change or be updated, or modules may be cancelled, over the duration of the course due to a number of reasons such as curriculum developments or staffing changes. Please refer to the module catalogue for information on available modules. This content was last updated on

Core

Industrial/Research Orientated Project

You’ll work on an individual project of direct industrial or research relevance which will be undertaken in collaboration with a suitable company, or research group within the university.

The project specification will be drawn up after you meet with your project supervisor and an advisor at the collaborating company.

You’ll work under the supervision of a member of staff with weekly individual tutorials and where appropriate, will maintain contact with the collaborating company through meetings and visits.

Optional

Advanced AC Drives
Advanced Control (autumn)

This module covers a range of advanced control techniques used in a wide range of engineering applications.

Typical topics include:

  • multivariable state space modelling
  • inear and nonlinear systems
  • continuous and discrete domains
  • observer theory.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 7 weeks 2 weeks 2 hours
Practicum 10 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 50%

Part 1: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 50% Formative health & safety risk assessment
Advanced Electrical Machines (spring)

This module introduces advanced electrical machine concepts and applications in the area of more electric transport, renewable generation and industrial automation.

The module will help you to:

  • develop a fundamental understanding of the interaction of the electromagnetic, mechanical and thermal engineering disciplines related to electrical machine design.
  • develop analytical skills in modelling and design of electrical machines.
  • have a clear understanding of the different types and topologies of modern electrical machines.
  • develop skills in designing electrical machines
  • develop the ability to analyse and characterise an electric motor through its parameters and performance using FEA approach

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 2 weeks 2 hours
Practicum  10 weeks 1 week 2 hours

 

Assessment method

Assessment Type Contribution Requirements
Coursework 25%

Part 1: weight 12.5%, 12.5 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: weight 25%, 12.5 hours of student effort; assessment of student ability to demonstrate application of the module's leaning outcomes to realistic engineering design and implement tasks.

Exam 75%  
Advanced Power Electronics

This module covers a range of advanced power electronic techniques and implementations for a variety of applications, including the design of power electronic converters for real applications. Both component-level design and the impact of non-idealities on modelling and operation are considered.

Method and Frequency of Class:

Activity Number of Weeks Number of sessions Duration of a session
Lecture 11 weeks 2 weeks 2 hours


Method of Assessment:

Assessment Type Contribution Requirements
Coursework 50%

Part 1: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 50%  
Applied Computational Engineering
Digital Signal Processing (autumn)

This module introduces the principles, major algorithms and implementation possibilities of digital signal processing at an advanced level.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 11 weeks 2 weeks 2 hours
Workshop 10 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 50%

Part 1: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 50%  
Distributed Generation and Alternative Energy (spring)

This module covers the operation of modern power systems including:

  • deregulated power systems
  • distributed generation
  • microgrids
  • the energy storage
  • technologies for producing clean energy
  • efficient HVDC power transmission

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 2 weeks 2 hours
Practicum  10 weeks 1 week 2 hours

 

Assessment method

Assessment Type Contribution Requirements
Coursework 1 50%

Part 1: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 1 50%  
HDL for Programmable Devices (spring)

The module introduces both the syntax and application of HDL for the design of modern electronics. This includes:

  • Xilinx
  • Mentor Graphics
  • combinational and sequential circuits design

You also be introduced to the VHDL syntax and its latest development. The module will use the software tools from both Xilinx and Mentor Graphics to present FPGA based digital system design flow with VHDL.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 7 weeks 2 weeks 3 hours
Practicum 4 weeks 1 week 3 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 50%

Part 1: weight 10%, 10 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: Weight 40%, 40 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 50%  
Instrumentation and Measurement (autumn)

This module is an introduction to the principles and practice of instrumentation and measurement systems in an engineering context.

The module will cover the generally applicable basic principles and then look at specific classes of instrument and associated electronics and signal processing methods.

Topics covered include:

  • Basic principles and instrument characteristics.
  • Measurement errors, basic statistics, noise and its control.
  • Dynamic characteristics of instruments, time and frequency domain responses.
  • System identification using correlation techniques.
  • Amplifiers, filters, ADCs and DACs.
  • Position, strain, pressure and motion sensors (resistive, capacitive, inductive, optical).
  • Flow sensors.    
  • Electronic and optical measurement instrumentation.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 11 weeks 2 weeks 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 50%

Coursework Part 1: weight 0.5, 25 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Coursework Part 2: weight 0.5, 25 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 50% 2 hour exam.
Microwave, Millimetre and Terahertz Systems (autumn)

This module introduces typical analytical, computational and experimental tools used in the study of electromagnetic fields and high frequency devices.

Fundamentals of electromagnetic wave propagation and typical passive microwave devices such as metal waveguides and devices in printed circuit technology are also introduced.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 11 weeks 2 weeks 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 50%

Part 1: 25% weight, 25 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: weight 25%. 25 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 50%  
Optical and Photonics Technology (spring)

This module covers selected topics from the interface between electronic and optical regimes. It includes issues regarding component, circuit, and system design, with applications to communications, material processing, biophotonics and optical imaging.

Method and Frequency of Class:

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 2 weeks 2 hours
Workshop 1 week 1 week 4 hours


Method of Assessment:

Assessment Type Weight Requirements
Coursework 50.00

Part 1: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module's learning outcomes.

Part 2: weight 25%, 25 hours of student effort; assessment of student ability to demonstrate application of the module's learning outcomes to realistic engineering design and implement tasks.

Exam 50.00  
Power Systems for Aerospace, Marine and Automotive (spring)

This module aims to develop an understanding of the design and operation of power systems in aerospace, marine and automotive applications.

With the introduction of more electrical technologies in these application areas, the understanding and expected performance of the power system has become a critical platform design issue.

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 2 week 2 hours
Practicum  10 weeks 1 week 2 hours

 

Assessment method

Assessment Type Weight Requirements
Coursework 25.00

Part 1: weight 12.5%, 12.5 hours of student effort; assessment of student ability to demonstrate fundamental acquisition of the module’s learning outcomes.

Part 2: weight 12.5%, 12.5 hours of student effort; assessment of student ability to demonstrate application of the module’s learning outcomes to realistic engineering design and implement tasks.

Exam 75.00

 

RF Electronics (spring)

This module covers the main concepts in design of high-speed circuits and devices including:

  • passive circuits,
  • amplifiers
  • active devices

Delivery

Activity Number of Weeks Number of sessions Duration of a session
Lecture 12 weeks 1 week 2 hours
Practicum 12 weeks 1 week 2 hours

Assessment method

Assessment Type Contribution Requirements
Coursework 50%

Part 1: 20 hours of student effort. Part 2: 30 hours of student effort.

Exam 50%  
The above is a sample of the typical modules we offer but is not intended to be construed and/or relied upon as a definitive list of the modules that will be available in any given year. Modules (including methods of assessment) may change or be updated, or modules may be cancelled, over the duration of the course due to a number of reasons such as curriculum developments or staffing changes. Please refer to the module catalogue for information on available modules. This content was last updated on

Fees and funding

UK students

£9,250
Per year

International students

To be confirmed in 2021*
Keep checking back for more information
*For full details including fees for part-time students and reduced fees during your time studying abroad or on placement (where applicable), see our fees page.

If you are a student from the EU, EEA or Switzerland starting your course in the 2022/23 academic year, you will pay international tuition fees.

This does not apply to Irish students, who will be charged tuition fees at the same rate as UK students. UK nationals living in the EU, EEA and Switzerland will also continue to be eligible for ‘home’ fee status at UK universities until 31 December 2027.

For further guidance, check our Brexit information for future students.

Scholarships and bursaries

The University offers a wide range of bursaries and scholarships. These funds can provide you with an additional source of non-repayable financial help:

Home students*

Over one third of our UK students receive our means-tested core bursary, worth up to £1,000 a year. Full details can be found on our financial support pages.

* A 'home' student is one who meets certain UK residence criteria. These are the same criteria as apply to eligibility for home funding from Student Finance.

International students

We offer a range of international undergraduate scholarships for high-achieving international scholars who can put their Nottingham degree to great use in their careers.

International scholarships

Careers

With the broad range of skills acquired from this degree, you will have excellent career prospects in areas including power distribution, future transport technologies (aerospace, rail, automotive) and industrial process control and automation.

Average starting salary and career progression

86.7% of undergraduates from the Department of Electrical and Electronic Engineering secured graduate level employment or further study within 15 months of graduation. The average annual salary for these graduates was £30,810.*

* HESA Graduate Outcomes 2020. The Graduate Outcomes % is derived using The Guardian University Guide methodology. The average annual salary is based on graduates working full-time within the UK.

Studying for a degree at the University of Nottingham will provide you with the type of skills and experiences that will prove invaluable in any career, whichever direction you decide to take.

Throughout your time with us, our Careers and Employability Service can work with you to improve your employability skills even further; assisting with job or course applications, searching for appropriate work experience placements and hosting events to bring you closer to a wide range of prospective employers.

Have a look at our careers page for an overview of all the employability support and opportunities that we provide to current students.

The University of Nottingham is consistently named as one of the most targeted universities by Britain’s leading graduate employers (Ranked in the top ten in The Graduate Market in 2013-2020, High Fliers Research).

Institute of Engineering and Technology

This course is accredited by the Institute of Engineering and Technology.

This degree has been accredited by the Institution of Engineering and Technology under licence from the UK regulator, the Engineering Council. Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC).

An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng).

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Important information

This online prospectus has been drafted in advance of the academic year to which it applies. Every effort has been made to ensure that the information is accurate at the time of publishing, but changes (for example to course content) are likely to occur given the interval between publishing and commencement of the course. It is therefore very important to check this website for any updates before you apply for the course where there has been an interval between you reading this website and applying.