BEng (Hons)
Electrical and Electronic Engineering
BEng (Hons)
Electrical and Electronic Engineering

Key Information


Duration

3 years

Typical Offer

See More

Campus

Brayford Pool

UCAS Code

H785

Duration

3 years

Typical Offer

See More

Campus

Brayford Pool

UCAS Code

H785

Academic Years

Course Overview

Electrical engineering is essential to the modern world, encompassing everything from energy and automation through to communications and transport. The BEng (Hons) Electrical and Electronic Engineering programme is designed to equip students with the skills needed by industry to deliver sustainable solutions, and to succeed as the engineers of the future.

Founded in collaboration with Siemens, the University of Lincoln's School of Engineering has a core philosophy of research-led teaching. Our innovative industrial collaborations have led to a rich programme of work experience opportunities, including at Siemens Energy in Lincoln.

Throughout the course, there are extensive opportunities at each level of study to engage in hands-on projects and benefit from learning in an environment where our academics and researchers are at the forefront of the industry and have expertise in a variety of electrical and electronic engineering disciplines. The curriculum support students to bridge the gap between university and the professional world by developing skills that are essential within the industry.

Strong links exist between our Mechanical and Electrical programmes, enabling our students to develop the strong cross-disciplinary focus necessary for the modern engineer, and an understanding of industry perspectives.

Course Overview

Electrical engineering is essential to the modern world, encompassing everything from energy and automation through to communications and transport. The BEng (Hons) Electrical and Electronic Engineering programme is designed to equip students with the skills needed by industry to deliver sustainable solutions, and to succeed as the engineers of the future.

Founded in collaboration with Siemens, the University of Lincoln's School of Engineering has a core philosophy of research-led teaching. Our innovative industrial collaborations have led to a rich programme of work experience opportunities, including at Siemens Energy in Lincoln.

Throughout the course, there are extensive opportunities at each level of study to engage in hands-on projects and benefit from learning in an environment where our academics and researchers are at the forefront of the industry and have expertise in a variety of electrical and electronic engineering disciplines. The curriculum supports students to bridge the gap between university and the professional world by developing skills that are essential within the industry.

Strong links exist between our Mechanical and Electrical programmes, enabling our students to develop the strong cross-disciplinary focus necessary for the modern engineer, and an understanding of industry perspectives.

Why Choose Lincoln

Accredited by the Institution of Engineering and Technology (IET)

Opportunities to spend an additional year in industry

Extensive hands-on project work

Strong industry links offer opportunities for placements, mentoring, and recruitment

Specialist purpose-built facilities and equipment

A range of optional modules to choose from

A student taking part in a practical session

How You Study

The course covers core electrical and electronic engineering subjects and provides opportunities to specialise in advanced electronics, power and energy, and control. Teaching and learning on the programme empower problem- and project-based learning to equip students with relevant in-depth knowledge, and essential practical and transferable skills that are a core requirement of the industry.

The first and second year of the Electrical and Electronic Engineering programmes offer a foundation in engineering theory and practice. Students can develop fundamental knowledge in areas such as robotics, semiconductor device physics, electrical technology, matter and interactions, engineering mathematics, and numerical computation.

Specialist modules in the third year include Power Electronics, Robotics and Automation, and Internet of Things and Smart Electronics. At each stage, students have opportunities to develop their engineering skills on real-life problems through project-based learning opportunities.

How You Study

The course covers core electrical and electronic engineering subjects and provides opportunities to specialise in advanced electronics, power and energy, and control. Teaching and learning on the programme empower problem- and project-based learning to equip students with relevant in-depth knowledge, and essential practical and transferable skills that are a core requirement of the industry.

The first and second year of the Electrical and Electronic Engineering programmes offer a foundation in engineering theory and practice. Students can develop fundamental knowledge in areas such as robotics, semiconductor device physics, electrical technology, matter and interactions, engineering mathematics, and numerical computation.

Specialist modules in the third year include Power Electronics, Robotics and Automation, and Internet of Things and Smart Electronics. At each stage, students have opportunities to develop their engineering skills on real-life problems through project-based learning opportunities.

Modules


† Some courses may offer optional modules. The availability of optional modules may vary from year to year and will be subject to minimum student numbers being achieved. This means that the availability of specific optional modules cannot be guaranteed. Optional module selection may also be affected by staff availability.

Computing and Programming for Engineers 2024-25EGR1013MLevel 42024-25Many sectors of engineering require high levels of computer literacy and the ability to write computer programs for problem solving is highly desirable. In learning the fundamentals of computer programming, logical thinking and problem solving, skills can be developed and coding techniques learnt, that can support the study of modules in forthcoming years. This course delivers the concepts of structured computer programming and lab time is allocated for implementing these concepts. Students are provided with opportunities to plan, write, and debug their own computer programs.CoreDesign Challenge for Engineers 2024-25EGR1022MLevel 42024-25All engineers must be familiar with design strategies, methods of assessing design proposals, approaches to reducing uncertainty, formal communication techniques, and the industrial and legal standards in which they fit. Mechanical Engineering students can independently learn and demonstrate the fundamentals of mechanical technical drawing and computer aided design (CAD), while Electrical Engineering students will independently learn and demonstrate the fundamentals of electrical drawing and CAD. Electrical and Mechanical engineers will then coalesce to form interdisciplinary groups who will produce an electro-mechanical design solution which meets a practical objective and considers the commercial, economic, social and environmental implications via a broad critique of the state of the art.CoreElectrical and Electronic Technology 2024-25ELE1004MLevel 42024-25An understanding of the basic principles and many of the important practical applications of electronic and electrical engineering is now essential to practitioners of other disciplines, especially mechanical engineers. The aim of this module is to provide a foundation in electrical engineering and electronics without being over complicated or cluttered with too-rigorous and exhaustive mathematical elements.CoreEngineering Mechanics 2024-25EGR1016MLevel 42024-25The module can be divided into two topics: Statics and Mechanics: The primary aim of the study of engineering mechanics is to develop students' capacity to predict the effects of force and deformation in the course of carrying out the creative design function of engineering. As students' undertake the study of solids and forces (first statics, mechanics, then dynamics) they can build a foundation of analytical capability for the solution of a great variety of engineering problems. Modern engineering practice demands a high level of analytical capability, and the study of mechanics can help in developing this. Dynamics: The study of dynamics gives students the opportunity to analyse and predict the motion of particles and bodies with and without reference to the forces that cause this motion. Successful prediction requires the ability of visualise physical configurations in terms of real machines ( in addition to knowledge of physical and mathematical principles of mechanics) and actual constraints and the practical limitations which govern the behaviour of machines.CoreMaterials and Methods of Manufacture 2024-25EGR1004MLevel 42024-25The selection of materials and manufacturing method is an integral part of the engineering design procedure. The purpose of this module is to introduce the fundamental properties of engineering materials through an understanding of the atomic and molecular interactions within the material. Students are introduced to the technology of manufacturing processes and how the selection of manufacturing processes are influenced by, and subsequently affect, material properties.CoreMathematical Skills for Engineers 2024-25EGR1014MLevel 42024-25A good mathematical grounding is essential for all engineers. The theory developed in this module aims to underpin the other engineering modules studied at level one. Wherever possible, mathematical theory is taught by considering a real example, to present students the mathematical tools they might need for the science they follow. Solutions are considered by both analytical and numerical techniques.CoreThermofluids 2024-25EGR1017MLevel 42024-25The syllabus for this module can be divided into two topics: Thermodynamics: Thermodynamics is an essential part of engineering curricula all over the world. It is a basic science that deals with energy interactions in physical systems, and the purpose of this module is to study the relationships between heat (thermos) and work (dynamics). This module presents a range of real-world engineering applications to give students a feel for engineering practice and an intuitive understanding of the subject matter. Fluid Mechanics: Fluid Mechanics is the branch of applied mechanics that is concerned with the statics and dynamics of liquids and gases. The analysis of the behaviour of fluids is based upon the fundamental laws of applied mechanics, which relate to the conservation of mass-energy and the force-momentum equation. However, instead of dealing with the behaviour of individual bodies of known mass, Fluid Mechanics is concerned with the behaviour of a continuous stream of fluid. For this reason, Fluid Mechanics is studied separately to other mechanics modules. Due to the similarity of the mathematical techniques, Fluid Mechanics are studied with Thermodynamics.CoreControl Systems 2025-26EGR2006MLevel 52025-26The aim of this module is to provide students with a firm grounding in Classical Control methods, which will enable them to work with systems and control engineers, and prepare students on the control stream for advanced topics in the level three and four modules. Students will be introduced to Control in relation to engineering systems, and in particular to develop methods of modelling the control of processes. Techniques are explored with particular reference to common practical engineering problems and their solutions, and the application of SIMULINK in this process.CoreData Modelling and Simulation 2025-26EGR2010MLevel 52025-26The purpose of this programme of mathematical study is to give students the opportunity to become more competent in calculations using a range of mathematical tools. The content builds upon that delivered in the first year, and gives students the opportunity to extend their analytical skills by introducing more advanced topics that may form part of the modern engineers skill set.CoreDigital Systems And Analog Electronics 2025-26BME2003MLevel 52025-26This modules introduces the basic knowledge required to understand, design, and work with basic electronic circuits and the basic principles underlying the process of electronic engineering. No previous electronics experience is assumed and the module proceeds via a sequence of lectures supported by labs designed to introduce practical electronics.CoreElectrical Power and Machines 2025-26ELE2004MLevel 52025-26Students will be introduced to electrical machines and power systems and their practical applications, supported by practical analysis/synthesis methods. This ability is fundamental for the students with mechanical engineering background, if they are to be able to handle electromechanical problems encountered in real life situations. Students will further have the opportunity to explore a general methodology for the calculation of electromechanical energy conversion. Students can obtain an appreciation of the features and characteristics of different types of electromechanical machines and drives and their applications.CoreIndustrial Engineering 2025-26EGR2011MLevel 52025-26This module aims to provide an introduction to the subject of industrial engineering. Industrial engineering is a branch of engineering dealing with the optimisation of complex processes or systems. It is concerned with the development, improvement, implementation and evaluation of integrated systems of people, economic resources, knowledge, information, equipment, energy, materials, analysis and synthesis, as well as the mathematical, physical and social sciences together with the principles and methods of engineering design to specify, predict, and evaluate the results to be obtained from such systems or processes. The various topics include management science, cost and value engineering, business economics and finance, engineering management, supply chain management, operations research, health and safety engineering, operation management.CoreInnovation Project 2025-26EGR2007MLevel 52025-26The content of this module aims to deepen a students’ understanding of engineering in practical applications. Students will have the opportunity to investigate the design process for mechanical, electrical or control components/systems and undertake analysis of the same. These two strands of the module are brought together in a design project, which will be set by a professional engineering organisation. This major project will give students the opportunity to extend their creative design skills and obtain practical experience of the process of creating sound conceptual solutions through to real design problems within an industrial context. Students can build confidence and gain experience through working within a team with practicing engineers from industry.CoreMechatronics Systems 2025-26ELE2003MLevel 52025-26The term mechatronics integrates mechanical engineering with electronics and intelligent computer control in the design and manufacture of products and processes. As a result, many products which used to have mechanical functions have had many replaced with ones involving microprocessors. This has resulted in much flexibility, easier redesign and reprogramming, and the ability to carry out automated data collection and reporting. A consequence of this approach is the need for engineers to adopt an interdisciplinary and integrated approach to engineering. The overall aim of this module is to give a comprehensive coverage of topics, such as analogue and digital signals, digital logic, sensors and signal conditioning, data acquisition systems, data presentation systems, mechanical and electrical actuation systems, microcontroller programming and interfacing, system response and modelling, and feedback control. Students may make extensive use of Simulink and a MATLAB support packages based an Arduino board, which allow for graphical simulation and programming of real-time control systems. The module serves as an introductory course to more advanced courses such as Measurement and Testing, Sensors, Actuators and Controllers, and Embedded Systems.CorePhysics of Electronic Devices 2025-26ELE2006Level 52025-26Students with an understanding of the physics underlying semiconductor devices and applications will be given the opportunity to study the processing of semiconductors to produce devices. Students will also establish an understanding of electrostatics, electromagnetics, and electroconductive fields and a revision of wave propagation and electromagnetic plane waves in free space and wave polarisation is covered. Relation between component size and EM wavelength such as qualitative introduction to antennas , circuit interference effects at high frequencies as well as skin effect.CoreEngineering Year in Industry 2025-26EGR2015XLevel 52025-26The Placement Year constitutes a work placement during an academic year, typically between Levels 2 and Level 3, though it may take place between levels 3 and 4 of an MEng programme. Students wishing to undertake the work placement year must successfully complete Level 2 (and 3 if applicable) of their programme. The Placement Year aims to give students a continuous experience of full-time work within an organisation. It should be a three-way co-operative activity between employer, student, and University. Work placements enable students to experience at first hand the daily workings of an organisation while setting that experience in the broader context of their studies.OptionalStudy Abroad Period: Engineering 2025-26EGR2019MLevel 52025-26This module provides an opportunity for students to spend a term in the second year studying at one of the University’s partner institutions abroad. Students wishing to take part in this must submit an application to the School discuss why they wish to participate in a study period abroad. A limited number of places will be available each year, and participation is subject to the School's approval.OptionalCommunication Systems 2026-27ELE3001MLevel 62026-27The module aims to enable students to gain knowledge and understanding of the principles and other key elements in communication systems and the theory involved in their design. Students are introduced to analogue and digital communication systems, as well as to the use of information theory in the framework of communication systems and their performance. An important aspect of this module is studying the topics of random processes and noise, sampling and quantization, and introducing students to key issues of filter design and modulation. Laboratory work will be carried out in Matlab/Simulink or equivalent software tool.CoreIndividual Project (Bachelors) 2026-27EGR3024MLevel 62026-27The individual project aims to provide students with a learning experience that enables them to carry out independent research, and to integrate many of the subjects they have studied throughout their degree. Students are expected to plan, research and execute their task while developing skills in critical judgement, independent work and engineering competence. Students have the opportunity to gain experience in presenting and reporting a major piece of engineering work, of immediate engineering value, at a level appropriate for an honours degree student.CoreIndustrial Automation 2026-27EGR3039MLevel 62026-27The aim of this module is to introduce students to modern industrial automation architectures. The module is composed of three parts: i) Sensors and actuators; ii) industrial networks; iii) Programmable logic controllers. In the first part students will have the opportunity to learn the main technological aspects of sensors and actuators used in industrial automation. The second part will explore how distributed architecture works, with an in-depth overview of the most common fieldbus and industrial Ethernet HW/SW protocols. The third part will explore Programmable Logic Controllers (PLCs) focusing both on the HW/SW architecture and on the main programming languages according to the IEEE61131-3 standard. Finally, students will also have the opportunity to gain hands-on experience by working on industrial automation test beds.CoreInternet of Things and Smart Electronics 2026-27ELE3006MLevel 62026-27This module is intended to introduce students with the fast growing area of consumer electronics design. Apart from interface and size issues, portable consumer electronics present some of the toughest design and engineering challenges in all of technology. This module breaks the complex design process down into its component parts, detailing every crucial issue from interface design to chip packaging, focusing upon the key design parameters of convenience, utility and size.CoreProgrammable Logic Design 2026-27ELE3004MLevel 62026-27In this module students will have the opportunity to work on the design of digital projects using Verilog for FPGA and ASIC implementation. Hierarchy of design abstraction and the process of top down design will also be covered, in addition to advanced concepts and methods of Verilog. Investigation of FPGA architectures issues involved in FPGA based implementations of advanced digital designs are illustrated by practical laboratories and assignments.CorePower Electronics 2026-27ELE3003MLevel 62026-27The aim of this module is to provide students with a thorough understanding of power electronics and electrical drives. The first part of the module begins with an overview of the main concepts behind electrical power processing and control. Power semiconductor switches are then introduced and their use as basic components in power electronics systems is deeply investigated. Subsequently, the main power converters architectures are defined and systematically analysed. The second part of the module aims to enable students to gain knowledge and understanding of classical electric machines and drives.OptionalRobotics and Automation 2026-27ELE3005MLevel 62026-27The aim of this module is to enable students to gain knowledge and understanding of the principles and other key elements in robotics, its interdisciplinary nature and its role and applications in automation. The module starts with the history and definition of robotics and its role in automation with examples. The module continues by studying a number of issues related to classifying, modelling and operating robots, followed by an important aspect of the robotics interdisciplinary nature i.e. its control and use of sensors and interpretation of sensory information as well as vision systems. Students will also have the opportunity to be introduced to the topics of networked operation and teleoperation, as well as robot programmingOptionalSignal Processing and System Identification 2026-27EGR3031MLevel 62026-27The aim of this module is to introduce students to theory and methodology of advanced techniques relevant to engineering systems, in order to design and implement filters and systems. System identification is a general term to describe mathematical tools and algorithms that build dynamic models from measured data. A dynamic model in this context is a mathematical description of the dynamic behaviour of a system or process in either the time or frequency domain. Students are given the opportunity to investigate methods by which they can perform useful operations on signals in either discrete or time-varying measurement.OptionalSmart Energy Systems 2026-27ELE3007MLevel 62026-27The purpose of this module is to analyse electrical machines, switched mode power-electronic convertors and design power systems for medium to high power applications. Students will have the opportunity to examine the operation characteristics and capabilities of commonly used systems and their control methods. In addition, students may examine the methods and issues surrounding transmission of electrical power, including insight and understanding of power system protection applications and the effects of system design on power quality.OptionalState-Space Control 2026-27EGR3032MLevel 62026-27In control engineering, a state-space representation is a mathematical model of a physical system as a set of input, output and state variables. Students have the opportunity to explore different methods of resolving the control variables in order to analyse systems in a compact and relevant way.Optional

Modules


† Some courses may offer optional modules. The availability of optional modules may vary from year to year and will be subject to minimum student numbers being achieved. This means that the availability of specific optional modules cannot be guaranteed. Optional module selection may also be affected by staff availability.

Computing and Programming for Engineers 2025-26EGR1013MLevel 42025-26Many sectors of engineering require high levels of computer literacy and the ability to write computer programs for problem solving is highly desirable. In learning the fundamentals of computer programming, logical thinking and problem solving, skills can be developed and coding techniques learnt, that can support the study of modules in forthcoming years. This course delivers the concepts of structured computer programming and lab time is allocated for implementing these concepts. Students are provided with opportunities to plan, write, and debug their own computer programs.CoreDesign Challenge for Engineers 2025-26EGR1022MLevel 42025-26All engineers must be familiar with design strategies, methods of assessing design proposals, approaches to reducing uncertainty, formal communication techniques, and the industrial and legal standards in which they fit. Mechanical Engineering students can independently learn and demonstrate the fundamentals of mechanical technical drawing and computer aided design (CAD), while Electrical Engineering students will independently learn and demonstrate the fundamentals of electrical drawing and CAD. Electrical and Mechanical engineers will then coalesce to form interdisciplinary groups who will produce an electro-mechanical design solution which meets a practical objective and considers the commercial, economic, social and environmental implications via a broad critique of the state of the art.CoreElectrical and Electronic Technology 2025-26ELE1004MLevel 42025-26An understanding of the basic principles and many of the important practical applications of electronic and electrical engineering is now essential to practitioners of other disciplines, especially mechanical engineers. The aim of this module is to provide a foundation in electrical engineering and electronics without being over complicated or cluttered with too-rigorous and exhaustive mathematical elements.CoreEngineering Mechanics 2025-26EGR1016MLevel 42025-26The module can be divided into two topics: Statics and Mechanics: The primary aim of the study of engineering mechanics is to develop students' capacity to predict the effects of force and deformation in the course of carrying out the creative design function of engineering. As students' undertake the study of solids and forces (first statics, mechanics, then dynamics) they can build a foundation of analytical capability for the solution of a great variety of engineering problems. Modern engineering practice demands a high level of analytical capability, and the study of mechanics can help in developing this. Dynamics: The study of dynamics gives students the opportunity to analyse and predict the motion of particles and bodies with and without reference to the forces that cause this motion. Successful prediction requires the ability of visualise physical configurations in terms of real machines ( in addition to knowledge of physical and mathematical principles of mechanics) and actual constraints and the practical limitations which govern the behaviour of machines.CoreMaterials and Methods of Manufacture 2025-26EGR1004MLevel 42025-26The selection of materials and manufacturing method is an integral part of the engineering design procedure. The purpose of this module is to introduce the fundamental properties of engineering materials through an understanding of the atomic and molecular interactions within the material. Students are introduced to the technology of manufacturing processes and how the selection of manufacturing processes are influenced by, and subsequently affect, material properties.CoreMathematical Skills for Engineers 2025-26EGR1014MLevel 42025-26A good mathematical grounding is essential for all engineers. The theory developed in this module aims to underpin the other engineering modules studied at level one. Wherever possible, mathematical theory is taught by considering a real example, to present students the mathematical tools they might need for the science they follow. Solutions are considered by both analytical and numerical techniques.CoreThermofluids 2025-26EGR1017MLevel 42025-26The syllabus for this module can be divided into two topics: Thermodynamics: Thermodynamics is an essential part of engineering curricula all over the world. It is a basic science that deals with energy interactions in physical systems, and the purpose of this module is to study the relationships between heat (thermos) and work (dynamics). This module presents a range of real-world engineering applications to give students a feel for engineering practice and an intuitive understanding of the subject matter. Fluid Mechanics: Fluid Mechanics is the branch of applied mechanics that is concerned with the statics and dynamics of liquids and gases. The analysis of the behaviour of fluids is based upon the fundamental laws of applied mechanics, which relate to the conservation of mass-energy and the force-momentum equation. However, instead of dealing with the behaviour of individual bodies of known mass, Fluid Mechanics is concerned with the behaviour of a continuous stream of fluid. For this reason, Fluid Mechanics is studied separately to other mechanics modules. Due to the similarity of the mathematical techniques, Fluid Mechanics are studied with Thermodynamics.CoreControl Systems 2026-27EGR2006MLevel 52026-27The aim of this module is to provide students with a firm grounding in Classical Control methods, which will enable them to work with systems and control engineers, and prepare students on the control stream for advanced topics in the level three and four modules. Students will be introduced to Control in relation to engineering systems, and in particular to develop methods of modelling the control of processes. Techniques are explored with particular reference to common practical engineering problems and their solutions, and the application of SIMULINK in this process.CoreData Modelling and Simulation 2026-27EGR2010MLevel 52026-27The purpose of this programme of mathematical study is to give students the opportunity to become more competent in calculations using a range of mathematical tools. The content builds upon that delivered in the first year, and gives students the opportunity to extend their analytical skills by introducing more advanced topics that may form part of the modern engineers skill set.CoreDigital Systems And Analog Electronics 2026-27BME2003MLevel 52026-27This modules introduces the basic knowledge required to understand, design, and work with basic electronic circuits and the basic principles underlying the process of electronic engineering. No previous electronics experience is assumed and the module proceeds via a sequence of lectures supported by labs designed to introduce practical electronics.CoreElectrical Power and Machines 2026-27ELE2004MLevel 52026-27Students will be introduced to electrical machines and power systems and their practical applications, supported by practical analysis/synthesis methods. This ability is fundamental for the students with mechanical engineering background, if they are to be able to handle electromechanical problems encountered in real life situations. Students will further have the opportunity to explore a general methodology for the calculation of electromechanical energy conversion. Students can obtain an appreciation of the features and characteristics of different types of electromechanical machines and drives and their applications.CoreIndustrial Engineering 2026-27EGR2011MLevel 52026-27This module aims to provide an introduction to the subject of industrial engineering. Industrial engineering is a branch of engineering dealing with the optimisation of complex processes or systems. It is concerned with the development, improvement, implementation and evaluation of integrated systems of people, economic resources, knowledge, information, equipment, energy, materials, analysis and synthesis, as well as the mathematical, physical and social sciences together with the principles and methods of engineering design to specify, predict, and evaluate the results to be obtained from such systems or processes. The various topics include management science, cost and value engineering, business economics and finance, engineering management, supply chain management, operations research, health and safety engineering, operation management.CoreInnovation Project 2026-27EGR2007MLevel 52026-27The content of this module aims to deepen a students’ understanding of engineering in practical applications. Students will have the opportunity to investigate the design process for mechanical, electrical or control components/systems and undertake analysis of the same. These two strands of the module are brought together in a design project, which will be set by a professional engineering organisation. This major project will give students the opportunity to extend their creative design skills and obtain practical experience of the process of creating sound conceptual solutions through to real design problems within an industrial context. Students can build confidence and gain experience through working within a team with practicing engineers from industry.CoreMechatronics Systems 2026-27ELE2003MLevel 52026-27The term mechatronics integrates mechanical engineering with electronics and intelligent computer control in the design and manufacture of products and processes. As a result, many products which used to have mechanical functions have had many replaced with ones involving microprocessors. This has resulted in much flexibility, easier redesign and reprogramming, and the ability to carry out automated data collection and reporting. A consequence of this approach is the need for engineers to adopt an interdisciplinary and integrated approach to engineering. The overall aim of this module is to give a comprehensive coverage of topics, such as analogue and digital signals, digital logic, sensors and signal conditioning, data acquisition systems, data presentation systems, mechanical and electrical actuation systems, microcontroller programming and interfacing, system response and modelling, and feedback control. Students may make extensive use of Simulink and a MATLAB support packages based an Arduino board, which allow for graphical simulation and programming of real-time control systems. The module serves as an introductory course to more advanced courses such as Measurement and Testing, Sensors, Actuators and Controllers, and Embedded Systems.CorePhysics of Electronic Devices 2026-27ELE2006Level 52026-27Students with an understanding of the physics underlying semiconductor devices and applications will be given the opportunity to study the processing of semiconductors to produce devices. Students will also establish an understanding of electrostatics, electromagnetics, and electroconductive fields and a revision of wave propagation and electromagnetic plane waves in free space and wave polarisation is covered. Relation between component size and EM wavelength such as qualitative introduction to antennas , circuit interference effects at high frequencies as well as skin effect.CoreEngineering Year in Industry 2026-27EGR2015XLevel 52026-27The Placement Year constitutes a work placement during an academic year, typically between Levels 2 and Level 3, though it may take place between levels 3 and 4 of an MEng programme. Students wishing to undertake the work placement year must successfully complete Level 2 (and 3 if applicable) of their programme. The Placement Year aims to give students a continuous experience of full-time work within an organisation. It should be a three-way co-operative activity between employer, student, and University. Work placements enable students to experience at first hand the daily workings of an organisation while setting that experience in the broader context of their studies.OptionalStudy Abroad Period: Engineering 2026-27EGR2019MLevel 52026-27This module provides an opportunity for students to spend a term in the second year studying at one of the University’s partner institutions abroad. Students wishing to take part in this must submit an application to the School discuss why they wish to participate in a study period abroad. A limited number of places will be available each year, and participation is subject to the School's approval.OptionalCommunication Systems 2027-28ELE3001MLevel 62027-28The module aims to enable students to gain knowledge and understanding of the principles and other key elements in communication systems and the theory involved in their design. Students are introduced to analogue and digital communication systems, as well as to the use of information theory in the framework of communication systems and their performance. An important aspect of this module is studying the topics of random processes and noise, sampling and quantization, and introducing students to key issues of filter design and modulation. Laboratory work will be carried out in Matlab/Simulink or equivalent software tool.CoreIndividual Project (Bachelors) 2027-28EGR3024MLevel 62027-28The individual project aims to provide students with a learning experience that enables them to carry out independent research, and to integrate many of the subjects they have studied throughout their degree. Students are expected to plan, research and execute their task while developing skills in critical judgement, independent work and engineering competence. Students have the opportunity to gain experience in presenting and reporting a major piece of engineering work, of immediate engineering value, at a level appropriate for an honours degree student.CoreIndustrial Automation 2027-28EGR3039MLevel 62027-28The aim of this module is to introduce students to modern industrial automation architectures. The module is composed of three parts: i) Sensors and actuators; ii) industrial networks; iii) Programmable logic controllers. In the first part students will have the opportunity to learn the main technological aspects of sensors and actuators used in industrial automation. The second part will explore how distributed architecture works, with an in-depth overview of the most common fieldbus and industrial Ethernet HW/SW protocols. The third part will explore Programmable Logic Controllers (PLCs) focusing both on the HW/SW architecture and on the main programming languages according to the IEEE61131-3 standard. Finally, students will also have the opportunity to gain hands-on experience by working on industrial automation test beds.CoreInternet of Things and Smart Electronics 2027-28ELE3006MLevel 62027-28This module is intended to introduce students with the fast growing area of consumer electronics design. Apart from interface and size issues, portable consumer electronics present some of the toughest design and engineering challenges in all of technology. This module breaks the complex design process down into its component parts, detailing every crucial issue from interface design to chip packaging, focusing upon the key design parameters of convenience, utility and size.CoreProgrammable Logic Design 2027-28ELE3004MLevel 62027-28In this module students will have the opportunity to work on the design of digital projects using Verilog for FPGA and ASIC implementation. Hierarchy of design abstraction and the process of top down design will also be covered, in addition to advanced concepts and methods of Verilog. Investigation of FPGA architectures issues involved in FPGA based implementations of advanced digital designs are illustrated by practical laboratories and assignments.CorePower Electronics 2027-28ELE3003MLevel 62027-28The aim of this module is to provide students with a thorough understanding of power electronics and electrical drives. The first part of the module begins with an overview of the main concepts behind electrical power processing and control. Power semiconductor switches are then introduced and their use as basic components in power electronics systems is deeply investigated. Subsequently, the main power converters architectures are defined and systematically analysed. The second part of the module aims to enable students to gain knowledge and understanding of classical electric machines and drives.OptionalRobotics and Automation 2027-28ELE3005MLevel 62027-28The aim of this module is to enable students to gain knowledge and understanding of the principles and other key elements in robotics, its interdisciplinary nature and its role and applications in automation. The module starts with the history and definition of robotics and its role in automation with examples. The module continues by studying a number of issues related to classifying, modelling and operating robots, followed by an important aspect of the robotics interdisciplinary nature i.e. its control and use of sensors and interpretation of sensory information as well as vision systems. Students will also have the opportunity to be introduced to the topics of networked operation and teleoperation, as well as robot programmingOptionalSignal Processing and System Identification 2027-28EGR3031MLevel 62027-28The aim of this module is to introduce students to theory and methodology of advanced techniques relevant to engineering systems, in order to design and implement filters and systems. System identification is a general term to describe mathematical tools and algorithms that build dynamic models from measured data. A dynamic model in this context is a mathematical description of the dynamic behaviour of a system or process in either the time or frequency domain. Students are given the opportunity to investigate methods by which they can perform useful operations on signals in either discrete or time-varying measurement.OptionalSmart Energy Systems 2027-28ELE3007MLevel 62027-28The purpose of this module is to analyse electrical machines, switched mode power-electronic convertors and design power systems for medium to high power applications. Students will have the opportunity to examine the operation characteristics and capabilities of commonly used systems and their control methods. In addition, students may examine the methods and issues surrounding transmission of electrical power, including insight and understanding of power system protection applications and the effects of system design on power quality.OptionalState-Space Control 2027-28EGR3032MLevel 62027-28In control engineering, a state-space representation is a mathematical model of a physical system as a set of input, output and state variables. Students have the opportunity to explore different methods of resolving the control variables in order to analyse systems in a compact and relevant way.Optional

What You Need to Know

We want you to have all the information you need to make an informed decision on where and what you want to study. In addition to the information provided on this course page, our What You Need to Know page offers explanations on key topics including programme validation/revalidation, additional costs, contact hours, and our return to face-to-face teaching.

What You Need to Know

We want you to have all the information you need to make an informed decision on where and what you want to study. In addition to the information provided on this course page, our What You Need to Know page offers explanations on key topics including programme validation/revalidation, additional costs, contact hours, and our return to face-to-face teaching.

How you are assessed

Assessment methods on the Electrical and Electronic Engineering programme aims to test engineering technical and analytical skills, as well as professional soft skills including oral and written communication, team working, long-life learning, problem-solving, project management, and planning and organisation.

The way students are assessed on this course may vary for each module. Examples of assessment methods that are used include time constrained assessments (TCAs), coursework, such as written assignments, reports, or dissertations; practical exams, such as presentations, performances, or observations; and written exams, such as formal examinations or in-class tests. The weighting given to each assessment method may vary across each academic year.

How you are assessed

Assessment methods on the Electrical and Electronic Engineering programme aims to test engineering technical and analytical skills, as well as professional soft skills including oral and written communication, team working, long-life learning, problem-solving, project management, and planning and organisation.

The way students are assessed on this course may vary for each module. Examples of assessment methods that are used include time constrained assessments (TCAs), coursework, such as written assignments, reports, or dissertations; practical exams, such as presentations, performances, or observations; and written exams, such as formal examinations or in-class tests. The weighting given to each assessment method may vary across each academic year.

Accreditation

This degree is accredited by the Institution of Engineering and Technology (IET), to enable students completing the programme the eventual opportunity to register as a Chartered Engineer (CEng). Further Master's-level accredited learning is required to complete the educational base for full CEng status.

IET Accredited Programme

Placements

A sandwich option is available on this programme, providing you with the opportunity to spend a year in industry. You are encouraged to obtain placements in industry independently, however tutors may provide support and advice to those who require it during this process. While undertaking placements, you are responsible for your own travel, living, and accommodation costs.

I have been supported in developing my professional skills to be on track for becoming a Chartered Engineer, and I have made the most of what the course has to offer to help me build confidence in my own academic ability. The academic staff are supportive and I know they want to help me achieve to the best of my ability.

Academic Expertise and Industry Links

Our academic team brings together a rich array of research experience, including staff with specialisms in diagnostics and prognostics, renewables, modelling of dynamic systems, nanomaterials, and applications of lasers. They secure grants for major UK and European research funders and deliver research, development, and consultancy for industrial partners, as well as being part of international research collaborations.

Students have the opportunity to engage in this research through research-led teaching and project work. The University of Lincoln’s School of Engineering has a core philosophy of research-led teaching. Our innovative industrial collaborations have led to a rich programme of work experience opportunities, including at Siemens Energy in Lincoln.

What Can I Do With an Electrical Engineering Degree?

The School of Engineering aims to prepare its graduates for a variety of career paths in areas such as energy, transportation, biomedical engineering, and microelectronics. This can include working with sensor networks, automotive electronics, in the microprocessor industry, and in the aerospace and satellite sectors.

Entry Requirements 2024-25

United Kingdom

104 UCAS Tariff points from a minimum of 2 A Levels or equivalent qualifications to include 40 points from Maths.

International Baccalaureate: Pass Diploma from a minimum of 2 Higher Level subjects to include a Higher Level 5 in Maths.

BTEC Extended Diploma in Engineering: Distinction, Merit, Merit or equivalent.

T Level: Merit in Engineering accepted.

Access to Higher Education Diploma: 45 Level 3 credits with a minimum of 104 UCAS Tariff points, including 40 points from 15 credits in Maths.

A combination of qualifications which may include A Levels, BTEC, EPQ, etc.

Applicants will also need at least three GCSEs at grade 4 (C) or above, which must include English and Maths. Equivalent Level 2 qualifications may also be considered.

The University accepts a wide range of qualifications as the basis for entry. We will also consider applicants with extensive and relevant work experience and will give special individual consideration to those who do not meet the standard entry qualifications.

International

Non UK Qualifications:

If you have studied outside of the UK, and are unsure whether your qualification meets the above requirements, please visit our country pages for information on equivalent qualifications.

https://www.lincoln.ac.uk/home/studywithus/internationalstudents/entryrequirementsandyourcountry/

EU and Overseas students will be required to demonstrate English language proficiency equivalent to IELTS 6.0 overall, with a minimum of 5.5 in each element. For information regarding other English language qualifications we accept, please visit the English Requirements page.

https://www.lincoln.ac.uk/home/studywithus/internationalstudents/englishlanguagerequirementsandsupport/englishlanguagerequirements/

If you do not meet the above IELTS requirements, you may be able to take part in one of our Pre-sessional English and Academic Study Skills courses.

https://www.lincoln.ac.uk/home/studywithus/internationalstudents/englishlanguagerequirementsandsupport/pre-sessionalenglishandacademicstudyskills/

For applicants who do not meet our standard entry requirements, our Science Foundation Year can provide an alternative route of entry onto our full degree programmes:

https://www.lincoln.ac.uk/home/course/sfysfyub/

If you would like further information about entry requirements, or would like to discuss whether the qualifications you are currently studying are acceptable, please contact the Admissions team on 01522 886097, or email admissions@lincoln.ac.uk

Contextual Offers

At Lincoln, we recognise that not everybody has had the same advice and support to help them get to higher education. Contextual offers are one of the ways we remove the barriers to higher education, ensuring that we have fair access for all students regardless of background and personal experiences. For more information, including eligibility criteria, visit our Offer Guide pages.

Entry Requirements 2025-26

United Kingdom

104 UCAS Tariff points from a minimum of 2 A Levels or equivalent qualifications to include 40 points from Maths.

BTEC Extended Diploma in Engineering: Distinction, Merit, Merit.

T Level in Engineering: Merit.

Access to Higher Education Diploma: 45 Level 3 credits with a minimum of 104 UCAS Tariff points, including 40 points from 15 credits in Maths.

International Baccalaureate: 28 points overall to include a Higher Level 5 in Maths.

GCSE's: Minimum of three at grade 4 or above, which must include English and Maths. Equivalent Level 2 qualifications may also be considered.


The University accepts a wide range of qualifications as the basis for entry and do accept a combination of qualifications which may include A Levels, BTECs, EPQ etc.

We may also consider applicants with extensive and relevant work experience and will give special individual consideration to those who do not meet the standard entry qualifications.

International

Non UK Qualifications:

If you have studied outside of the UK, and are unsure whether your qualification meets the above requirements, please visit our country pages for information on equivalent qualifications.

https://www.lincoln.ac.uk/home/studywithus/internationalstudents/entryrequirementsandyourcountry/

EU and Overseas students will be required to demonstrate English language proficiency equivalent to IELTS 6.0 overall, with a minimum of 5.5 in each element. For information regarding other English language qualifications we accept, please visit the English Requirements page.

https://www.lincoln.ac.uk/home/studywithus/internationalstudents/englishlanguagerequirementsandsupport/englishlanguagerequirements/

If you do not meet the above IELTS requirements, you may be able to take part in one of our Pre-sessional English and Academic Study Skills courses.

https://www.lincoln.ac.uk/home/studywithus/internationalstudents/englishlanguagerequirementsandsupport/pre-sessionalenglishandacademicstudyskills/

For applicants who do not meet our standard entry requirements, our Science Foundation Year can provide an alternative route of entry onto our full degree programmes:

https://www.lincoln.ac.uk/home/course/sfysfyub/

If you would like further information about entry requirements, or would like to discuss whether the qualifications you are currently studying are acceptable, please contact the Admissions team on 01522 886097, or email admissions@lincoln.ac.uk

Contextual Offers

At Lincoln, we recognise that not everybody has had the same advice and support to help them get to higher education. Contextual offers are one of the ways we remove the barriers to higher education, ensuring that we have fair access for all students regardless of background and personal experiences. For more information, including eligibility criteria, visit our Offer Guide pages.

Fees and Scholarships

Going to university is a life-changing step and it's important to understand the costs involved and the funding options available before you start. A full breakdown of the fees associated with this programme can be found on our course fees pages.

Course Fees

For eligible undergraduate students going to university for the first time, scholarships and bursaries are available to help cover costs. To help support students from outside of the UK, we are also delighted to offer a number of international scholarships which range from £1,000 up to the value of 50 per cent of tuition fees. For full details and information about eligibility, visit our scholarships and bursaries pages.

Fees and Scholarships

Going to university is a life-changing step and it's important to understand the costs involved and the funding options available before you start. A full breakdown of the fees associated with this programme can be found on our course fees pages.

Course Fees

For eligible undergraduate students going to university for the first time, scholarships and bursaries are available to help cover costs. To help support students from outside of the UK, we are also delighted to offer a number of international scholarships which range from £1,000 up to the value of 50 per cent of tuition fees. For full details and information about eligibility, visit our scholarships and bursaries pages.

Find out More by Visiting Us

The best way to find out what it is really like to live and learn at Lincoln is to visit us in person. We offer a range of opportunities across the year to help you to get a real feel for what it might be like to study here.

Book Your Place
Three students walking together on campus in the sunshine
The University intends to provide its courses as outlined in these pages, although the University may make changes in accordance with the Student Admissions Terms and Conditions.