These modules will focus upon the development of highly transferable practical skills relevant to specific sectors through which change can be affected. In this module we will explore the ways in which history and the humanities can be leveraged to effect change through the policy sector (e.g. civil service, local govt., consultancy, risk analysis) and public advocacy (e.g. charities, think tanks, public campaigning). The module’s Communication Workshops will train participants in the production of two specific outputs: concise policy briefs aimed at policy makers, and compelling opinion pieces intended for the general public. Digital Humanities Workshops will develop skills in data analysis and data visualisation to enhance the impact of these outputs.
These modules will focus upon the development of highly transferable practical skills relevant to specific sectors through which change can be affected. In this module we will explore how public history (e.g. exhibitions, magazines, documentaries, entertainment) and education (e.g. curriculum development, classroom resources) can address contemporary global and local challenges and effect change within society. The module’s Communication Workshops will focus upon the development of two specific outputs: public exhibitions and classroom lesson plans. Digital Humanities workshops will develop skills in the production of video essays and podcasts to enhance the impact of these outputs.
This module will focus on examining various aspects of teaching and learning and how they relate to theory, research and your own practice. In this module you will examine a range of concepts and theories from education, sociology and psychology that describe how children, adolescents and adults learn and study. You will also examine research on different approaches to teaching and learning, factors that influence them, and implications for practice.
This module is the lab programme for all first-year students enrolled on an ELEC degree programme. It aims to give students the opportunity to apply the theory that they learn in their other modules, and to provide them with transferrable, subject-based and professional skills that they will need for their degree and career. Structurally, the ELEC Part One Laboratory Programme is organised to cover all practical and laboratory based work in the first year of study on all ELEC Programmes in a single timetable organised into central laboratory locations. The module is structured into a series of activities. There are a series of general sessions which all students enrolled on this module are expected to attempt: •Information lectures. •Transferable skills laboratories •Professional skills laboratories. •Assignments. In addition, there are a number of technical laboratories integrated into the Laboratory Programme which cover practical Learning Outcomes from other technical modules in the Programmes.
This module provides the students with the opportunity to gain experience in different health, social or community care settings which can be in the UK or abroad - in accordance with prevailing University and Foreign-Commonwealth Office travel guidance. The module will normally take the format of 8 week placement in one or more healthcare or suitable alternative settings. The timing will vary for different student groups and the teaching staff will vary for different practices and student groups. As is the nature of the elective, the exact learning experiences of each student will be variable. However, all students should receive the same broad opportunities sufficient to achieve the learning outcomes of the module and it is expected that students will take responsibility for making the most of the opportunities provided. Students should be pro-active in securing experiences in areas in which they feel they are weak and/or in which they would like to gain more experience. Alternatively students may wish to explore a specialist interest or experience a non-NHS healthcare setting, including charitable organisations, care agencies or research. Further details will be provided on Blackboard.
It is difficult to imagine what the world would be like without electricity: homes without electric light, without television or radio, without motors to drive the washing machine, the refrigerator and the vacuum cleaner; offices without computers, word processors, telephones and photocopiers. It is almost impossible to think of a railway system without electric signalling and control or a factory production line without electric drives. Wherever we turn we see electricity at work distributing energy, transmitting information, and controlling every conceivable process. While it is certainly possible to build a mechanical system (mechanisms or machines) with mechanical components only (e.g. early steam engines, boats and aeroplanes), it is more common to see mechanical systems comprising a mix of mechanical and electrical components or mechatronic systems. Modern cars, boats, aeroplanes, robots and digital cameras are good examples. Learning the subject of electricity is therefore vital to all engineering disciplines including mechanical engineering, aeronautics and astronautics engineering, acoustic engineering and ship science. Not only that a mechanical/aero/astro/acoustic/ship Engineer need to be able to communicate with other electrical and electronic engineers in a multidisciplinary project he/she will often find themselves having to actually design or operate the electrical or electronic subsystems. The aim of this module is to introduce the subject of electricity and electrical systems focusing on the fundamentals of the subject in the context of applications in the areas of mechanical, aero, acoustic and ship engineering. These application areas are primarily in the areas of measurement and control. The fundamentals introduced in this module will be built on by other subjects such as advanced modules on electrical and electronic systems, measurement and instrumentation modules, avionics and control system modules. Additionally, some of the mathematical techniques applied to circuit analysis are also applicable to the analysis of heat transfer problems, mechanical system dynamics, fluid flow in pipes and others
This module equips students with a comprehensive understanding of how mechanical systems move and deform when subjected to external forces. We then progress to advanced topics including buckling and deformation of mechanical structures such as beams and cantilevers. The second part of the module covers materials response to applied electric and magnetic fields, e.g. polarisation and conduction in dielectrics, magnetisation and ferromagnetism. Materials for novel and emerging applications are considered as well, e.g. high-voltage cable insulations, electret materials, triboelectric series, piezo-electricity, ferro-electricity, pyroelectricity. The module includes one laboratory analysis covering dielectric material characterisation and one laboratory experiments on deformation of beams. Students will be supported by examples and tutorial questions with many real-life practical examples.
The module aims to provide a detailed understanding of all aspects of the selection, sizing and operation of modern electrical machines and drive systems. Through the module, students will be able to learn to design electromechanical devices, identify different types of electrical machines and their suitability for different applications. The derivation of equations describing operation of machines, formulate relevant equivalent circuits and analyse simple problems related to operation of electrical machines and drives will be studied.
This module offers an introduction to the scientific principles and methods of electricity and electronics.
The major concepts covered are: - The abstraction from forces to fields using the examples of the electric and magnetic fields, with some applications - The connection between conservative forces and potential energy - How charges move through electric circuits - The close connection between electricity and magnetism, leading to the discovery of electromagnetic waves. - the integral form of Maxwell's Equations
Electroacoustic transducers, such as microphones and loudspeakers, are commonplace in the fields of acoustics and audio and it is important that acoustical engineers have an understanding of the theory and mechanisms of electroacoustic transduction. This module provides the knowledge to understand and predict the behaviour of a wide range of electroacoustic devices, and to relate this to real-world transducer technology.
Electromagnetism is one of the brilliant successes of nineteenth century physics and the equations formulated by Maxwell are believed to account exactly for all classical electromagnetic phenomena. The aim of this course is to present the laws of electromagnetism, their experimental justification, and their application to physical phenomena.
