BEng (Hons) ELECTRICAL POWER ENGINEERING (WITH FOUNDATION YEAR) draft

This module provides you with the mathematical knowledge and skills to support study of BEng programmes. The module covers basic algebra, liner and simultaneous equations, quadratic equations, and graphical methods.

The module will cover the principles of chemistry and physics, at a level between GCSE and A-level. It will introduce you to a range of skills required in both chemical and physical sciences, as appropriate to your intended programme of study.

The module introduces study skills considering both individual and team-working skills. It will also introduce you to your own Personal Development Planning process. This module will enable you develop and use appropriate safe working practices in the workshop or laboratory environment specific to your subject/discipline.

This module will provide you with the mathematical knowledge and skill necessary for transition to level 4 study of engineering subjects. You’ll attend lectures and tutorial where worked exercises will be undertaken. Where possible, the statistical content will introduce the use of statistical packages and the presentation of real-life data sets

This is an introductory module to engineering design. You’ll be taught the basic design process and apply this to a simple product. You’ll also be introduced to the workshop and simple model making tools. You’ll learn basic drawings skills.

This module provides you with the principles of chemistry and its applications to support study of BEng programmes. It covers fundamentals of chemistry and chemical reactions, and the skills necessary for effective communication in scientific and technical subjects.

This module consolidates the mathematical skills that underpin the BEng engineering degrees. It is specifically designed to cater for the wide differences in mathematical background of 1st year engineering students. Mathematics background is necessary to produce a competent electronic and computer systems engineer. Additionally, it aims to introduce students to the Matlab computing environment.

This module introduces the syntaxes and semantics of programming language C++ and teaches students the intellectual knowledge in programming principles and programming skills with Object Oriented Programming (OOP) techniques. The practical skills include C++ program design with OOP and the use of the compiling tools for editing, compiling, linking and executing programs in workshops. After learning this module, students can pursue other software engineering and advanced programming courses and use OOP techniques to solve simple engineering problems. This module aims to provide students with intermediate proficiency in the use of the C++ programming languages and further to write efficient OOP programs making use of data classes.

This module is developed to provide students the knowledge of analysing DC and AC electrical circuits. It provides cornerstone skills required in the fields of electrical and electronic engineering, computer systems engineering and mechanical engineering. The course content covers electrical units, measuring instruments, series/parallel DC circuit analysis, storage elements analysis, AC waveforms, R, L, C, RL and RLC AC circuits with phasor analysis, electromagnetism, equivalent circuit of single phase transformer and three phase circuits including Star/Delta winding configurations and analysing the power in the balanced star/delta connected loads with symmetrical three phase supplies.

The module covers the fundamental theory for the design of and the practical uses of digital electronics in the two design domains of combinational logic design and sequential logic design. The process of developing digital logic design is modelled using Hardware Description Languages (HDL). The module studies hardware devices to build circuits for digital logic designs and tools to support the design and analysis of those circuits; these include standard logic gates and Field Programmable Gate Arrays (FPGA). The module covers common design blocks such as adders, encoders, comparators, data selectors, flip-flops, counters, registers. The module shows the design and implementation of fully digital systems typically based around finite state machines from description in HDL to implementation using FPGA technology.

This module introduces the physics of semiconductor devices by exploring the basic atomic theory, the flow of charge in materials, conduction mechanisms involved, the formation of bipolar semiconductor junctions, energy band diagrams, breakdown mechanisms and the operation of these solid-state devices (e.g. diodes and transistors).

This is a common module for all undergraduate year one engineering students. It provides core study skills, contextualised for engineering students. The module addresses the following: Design activities, teamwork, creative problem solving, project management, sustainable development principles, personal development planning, report writing communication, Computer-Aided Design (CAD),  Printed Circuit Board (PCB) designs and supports employability and transferable skills. The aim of the module is for students to begin their engagement with engineering design and with studying engineering in Higher Education.

This module covers undergraduate advanced engineering mathematics to enable you to consider and model a variety of relevant engineering problems (e.g. electrical, mechanical, petroleum, chemical, computer, civil).

This module introduces methods to mathematically model circuits, signals and systems required for the engineering of electrical, electronic, telecommunication and control systems. It shows how to model and analyse complex signals with Fourier series, Fourier transforms and Laplace Transforms. The direct and indirect method of convolution is used to find the time response of systems to given inputs. First and second order LTI dynamical systems are modelled with transfer functions and their zero-state and zero-input responses predicted when the inputs are any function of time. The frequency responses of some common LTI two port filter circuits are studied. A MATLAB/SIMULINK workshop enables understanding of signal synthesis using the Fourier series, finding the frequency spectra of complex and noisy signals using FFT, and the time response and the frequency response of systems.

This module aims to give a sound understanding of a range of topics in Control Systems Engineering. It will impart methods to model and analyse dynamical systems met in the engineering of systems such as robotics, automobiles, aircraft, automatic machinery, chemical process plant, etc. It will teach you to determine the stability of a system and to predict system responses in the time domain (transient and steady state) and in the frequency domain, as well as to handle the interconnection of many Single Input Single Output systems connected in feedback and feed forward configurations. The module will provide you with methods to specify supervisory control and data acquisition systems, and to modify the behaviour of a given system by using feedback control to improve stability, to make the system act quickly and precisely, and to reduce the effect of disturbances. Learning will be supported by a laboratory workshop that enables the study of control systems using both analysis methods and computer simulation using MATLAB and SIMULINK.

This module will enable students to develop an understanding of the electrical technology and systems that go into modern buildings. It covers material about the electrical services that form part of a modern building and final circuit design, plant sizing, related standards, etc. It also covers topics such as Lighting, Earthing and CPC calculations as applied to the design of building services. The nature and specification of the requirements are considered as well as the types of engineering systems that can be used to satisfy the requirements. In addition, Lightning protection for buildings and the various regulatory aspects are covered. The module provides broad intermediate-level coverage and motivation for more advanced treatment of electrical services and distribution in later modules. Students will be trained to produce optimum, safe, reliable, environmentally friendly, energy-efficient and cost-effective systems/services designs for the modern built environment.

This module adopts a modern approach to the study of electrical machines, 3-phase transformers and power electronic converters. The treatment emphasises the features common to all types of electrical machines and power electronic converters and then develops basic performance equations and equivalent circuits and applies them to common electrical machines and power converters in current use. The associated laboratory workshop features work on typical electrical machines and power converters.

This is a skills-based module developing students' understanding of the design process within engineering, including factors that need to be taken into account in identifying and meeting requirements for new products, i.e. outcomes of processes; working within Regulatory, professional and Standards requirements; developing practical skills; working as part of a team; handling information; project planning and management; and report-writing and presentation skills.

This module establishes the students’ knowledge in all types of renewable energy systems. It provides cornerstone renewable energy engineering skills required in the fields of electrical and electronic engineering and electrical power engineering. The contents entails calculations and measurement methods of solar radiation and the theory of photovoltaics and its performance parameters. These will be applied in designing and analysing the photovoltaic technologies. This module also enlightens the design, development and performance analyses of wind energy technologies. Students’ will also advance their knowledge of smart grid interconnected wind energy and photovoltaic systems, supported by workshop experiments.

This module is designed to equip students with the up-to-date knowledge and skills to enable them to work in the electrical building services industry; design, installation, manufacturing, operation and maintenance. The module covers, UPS systems, Lift systems, Advanced power factor correction, Risk and reliability aspects of systems and services, energy management, EMC, LAN/WANS. The students Produce engineering designs that are not only technically sound, but also safe, reliable cost effective, and environmentally friendly and where possible sustainable.

The material in this module covers the analysis and operation of power transmission and distribution networks at 11kV and above forming the ‘supply’ side of electrical power networks, under both steady state and transient conditions. It provides a broad understanding of the elements of power systems and advanced aspects of power transmission, fault analysis and protection integrated into the supply network. It is suitable for students who work in organisations that specify, design, commission, operate and maintain all types of electrical power infrastructure and/or who wish to pursue further study afterwards at master’s level or above. Students will be equipped with the essential theory and practice enabling them to assess modern trends in the subject and maintain and update their knowledge.

This module provides a broad understanding of the theory and application of power electronic circuits in the areas of power conversion and electrical machine drives. The material covered is particularly relevant to students in the area of electrical building services, where a significant proportion of electrical plant and drives will have power electronics and microprocessor control components. It's suitable for students who work in organisations that specify, design, commission, operate and maintain all types of electrical power infrastructure and/or who wish to pursue further study afterwards at Masters level or above. You'll be equipped with the essential theory and practice, enabling you to assess modern trends in the subject and maintain and update your knowledge. Assessment methods: 30% coursework, 70% exam.

The individual major project requires students to plan, execute, review and report upon a major piece of technical work directly related to their degree discipline. In this regard, it provides students with the opportunity to develop a high degree of subject specific expertise. This module differentiates from others on the course taken due to the high degree of autonomous study expected. This flexibility should be seen as an opportunity to explore new areas of interest and to acquire new and often unexpected skills.

This module consolidates the mathematical skills that underpin the BEng engineering degrees. It is specifically designed to cater for the wide differences in mathematical background of 1st year engineering students. Mathematics background is necessary to produce a competent electronic and computer systems engineer. Additionally, it aims to introduce students to the Matlab computing environment.

This module introduces the syntaxes and semantics of programming language C++ and teaches students the intellectual knowledge in programming principles and programming skills with Object Oriented Programming (OOP) techniques. The practical skills include C++ program design with OOP and the use of the compiling tools for editing, compiling, linking and executing programs in workshops. After learning this module, students can pursue other software engineering and advanced programming courses and use OOP techniques to solve simple engineering problems. This module aims to provide students with intermediate proficiency in the use of the C++ programming languages and further to write efficient OOP programs making use of data classes.

This module is developed to provide students the knowledge of analysing DC and AC electrical circuits. It provides cornerstone skills required in the fields of electrical and electronic engineering, computer systems engineering and mechanical engineering. The course content covers electrical units, measuring instruments, series/parallel DC circuit analysis, storage elements analysis, AC waveforms, R, L, C, RL and RLC AC circuits with phasor analysis, electromagnetism, equivalent circuit of single phase transformer and three phase circuits including Star/Delta winding configurations and analysing the power in the balanced star/delta connected loads with symmetrical three phase supplies.

This is a common module for all undergraduate year one engineering students. It provides core study skills, contextualised for engineering students. The module addresses the following: Design activities, team work, creative problem solving, project management, sustainable development principles, personal development planning, report writing communication, Computer-Aided Design (CAD),  Printed Circuit Board (PCB) designs and supports employability and transferable skills. The aim of the module is for students to begin their engagement with engineering design and with studying engineering in Higher Education.

The module covers the fundamental theory for the design of and the practical uses of digital electronics in the two design domains of combinational logic design and sequential logic design. The process of developing digital logic design is modelled using Hardware Description Languages (HDL). The module studies hardware devices to build circuits for digital logic designs and tools to support the design and analysis of those circuits; these include standard logic gates and Field Programmable Gate Arrays (FPGA). The module covers common design blocks such as adders, encoders, comparators, data selectors, flip-flops, counters, registers. The module shows the design and implementation of full digital systems typically based around finite state machines from description in HDL to implementation using FPGA technology.

This module introduces the physics of semiconductor devices by exploring basic atomic theory, the flow of charge in materials, conduction mechanisms involved, the formation of bipolar semiconductor junctions, energy band diagrams, breakdown mechanisms and the operation of these solid-state devices (e.g. diodes and transistors).

This module covers undergraduate advanced engineering mathematics to enable you to consider and model a variety of relevant engineering problems (e.g. electrical, mechanical, petroleum, chemical, computer, civil).

This module introduces methods to mathematically model circuits, signals and systems required for the engineering of electrical, electronic, telecommunication and control systems. It shows how to model and analyse complex signals with Fourier series, Fourier transforms and Laplace Transforms. The direct and indirect method of convolution is used to find the time response of systems to given inputs. First and second order LTI dynamical systems are modelled with transfer functions and their zero-state and zero-input responses predicted when the inputs are any function of time. The frequency responses of some common LTI two port filter circuits are studied. A MATLAB/SIMULINK workshop enables understanding of signal synthesis using the Fourier series, finding the frequency spectra of complex and noisy signals using FFT, and the time response and the frequency response of systems.

This module aims to give a sound understanding of a range of topics in Control Systems Engineering. It will impart methods to model and analyse dynamical systems met in the engineering of systems such as robotics, automobiles, aircraft, automatic machinery, chemical process plant, etc. It will teach you to determine the stability of a system and to predict system responses in the time domain (transient and steady state) and in the frequency domain, as well as to handle the interconnection of many Single Input Single Output systems connected in feedback and feed forward configurations. The module will provide you with methods to specify supervisory control and data acquisition systems, and to modify the behaviour of a given system by using feedback control to improve stability, to make the system act quickly and precisely, and to reduce the effect of disturbances. Learning will be supported by a laboratory workshop that enables the study of control systems using both analysis methods and computer simulation using MATLAB and SIMULINK.

This level 5 module will enable students to develop an understanding of the electrical technology and systems that go into modern buildings. It covers material about the electrical services that form part of a modern building and final circuit design, plant sizing, related standards, etc. It also covers topics such as Lighting, Earthing and CPC calculations as applied to the design of building services. The nature and specification of the requirements are considered as well as the types of engineering systems that can be used to satisfy the requirements. In addition, Lightning protection for buildings and the various regulatory aspects are covered. The module provides broad intermediate level coverage and motivation for more advanced treatment of electrical services and distribution in later modules. Students will be trained to produce optimum, safe, reliable, environmentally friendly, energy-efficient and cost-effective systems / services designs for the modern built environment.

This module adopts a modern approach to the study of electrical machines, 3-phase transformers and power electronic converters. The treatment emphasises the features common to all types of electrical machines and power electronic converters and then develops basic performance equations and equivalent circuits and applies them to common electrical machines and power converters in current use. The associated laboratory workshop features work on typical electrical machines and power converters.

This is a skills-based module developing your understanding of the design process within engineering, including factors that need to be taken into account in identifying and meeting requirements for new products(used to mean outcome of a process and can include specifications for a tangible product, or process, or system), such as working within Regulatory, professional and Standards requirements, developing practical skills, working as part of a team, handling information, project planning and management, and report-writing and presentation skills. .

This module establishes the students’ knowledge in all types of renewable energy systems. It provides cornerstone renewable energy engineering skills required in the fields of electrical and electronic engineering and electrical power engineering. The contents entails calculations and measurement methods of solar radiation and the theory of photovoltaics and its performance parameters. These will be applied in designing and analysing the photovoltaic technologies. This module also enlightens the design, development and performance analyses of wind energy technologies. Students’ will also advance their knowledge of smart grid interconnected wind energy and photovoltaic systems, supported by workshop experiments.

This module is designed to equip students with the up-to-date knowledge and skills to enable them to work in the electrical building services industry; design, installation, manufacturing, operation and maintenance. The module covers, UPS systems, Lift systems, Advanced power factor correction, Risk and reliability aspects of systems and services, energy management, EMC, LAN/WANS. The students Produce engineering designs that are not only technically sound, but also safe, reliable cost effective, and environmentally friendly and where possible sustainable.

The material in this module covers the analysis and operation of power transmission and distribution networks at 11kV and above forming the ‘supply’ side of electrical power networks, under both steady state and transient conditions. It provides a broad understanding of the elements of power systems and advanced aspects of power transmission, fault analysis and protection integrated into the supply network. It is suitable for students who work in organisations that specify, design, commission, operate and maintain all types of electrical power infrastructure and/or who wish to pursue further study afterwards at master’s level or above. Students will be equipped with the essential theory and practice enabling them to assess modern trends in the subject and maintain and update their knowledge.

This module provides a broad understanding of the theory and application of power electronic circuits in the areas of power conversion and electrical machine drives. The material covered is particularly relevant to students in the area of electrical building services, where a significant proportion of electrical plant and drives will have power electronics and microprocessor control components. It's suitable for students who work in organisations that specify, design, commission, operate and maintain all types of electrical power infrastructure and/or who wish to pursue further study afterwards at Masters level or above. You'll be equipped with the essential theory and practice, enabling you to assess modern trends in the subject and maintain and update your knowledge. Assessment methods: 30% coursework, 70% exam.

The individual major project requires students to plan, execute, review and report upon a major piece of technical work directly related to their degree discipline. In this regard, it provides students with the opportunity to develop a high degree of subject specific expertise. This module differentiates from others on the course taken due to the high degree of autonomous study expected. This flexibility should be seen as an opportunity to explore new areas of interest and to acquire new and often unexpected skills.