Run by School of Computer Science and Electronic Engineering
10 Credits or 5 ECTS Credits
Organiser: Prof Paul Spencer
Overall aims and purpose
To introduce electromagnetics and the necessary vector calculus required to appreciate the subject. To derive the electromagnetic wave equation and solve one-dimensional problems.
• Vectors: Concept and definition. Addition, subtraction, components. Vector multiplication: dot and cross products. Volume integral (scalar), line integral (vector). Differentiation of vectors: Div, Grad and Curl. Triple scalar and vector products. Stoke’s theorem and Divergence theorem.
• Charge and electric flux: force on a charge, Gauss’ law. Capacitance. Electrostatic force and energy storage. Magnetic field and flux. Lorentz force. Ampere’s Law. Biot-Savart Law. Faraday’s and Lenz’s law. Inductance.
• E-M waves and Maxwell’s equations. Displacement current and continuity equation
Learning outcomes mapped to assessment criteria
Have an understanding of basic concepts in electricity and magnetism
|Can apply the laws to unseen problems||Can state the basic laws of electrostatics and magneto statics. Capable of basic mathematical manipulations.||Understands the basic laws of electrostatics and magneto statics and can apply to simple problems.|
Have an understanding of the unification of electricity and magnetism into Maxwell’s equations and their application.
|Can derive the e/m wave equation from Maxwell’s equations.||Can state Maxwell’s equations. Capable of basic mathematical manipulations.||Can state Maxwell’s equations and understand concepts involved|
Able to use vector calculus.
|Able to use the laws of vector algebra to determine electric and magnetic fields||Can state the laws of vector algebra. Capable of basic mathematical manipulations||Can apply to vector calculus to unseen problems.|
|Mathematical exercise on the fundamentals of Vector Calculus||15|
|Mathematical exercises that test ability to solve standard EM problems||15|
Teaching and Learning Strategy
3 x 1 hour lectures/tutorial sessions per week over 12 weeks
Background reading and application of techniques to problems using tutorial sheets and past papers. Review of recommended text and blackboard content. Review of past papers.
- Literacy - Proficiency in reading and writing through a variety of media
- Numeracy - Proficiency in using numbers at appropriate levels of accuracy
- Computer Literacy - Proficiency in using a varied range of computer software
- Self-Management - Able to work unsupervised in an efficient, punctual and structured manner. To examine the outcomes of tasks and events, and judge levels of quality and importance
- Critical analysis & Problem Solving - Able to deconstruct and analyse problems or complex situations. To find solutions to problems through analyses and exploration of all possibilities using appropriate methods, rescources and creativity.
- Presentation - Able to clearly present information and explanations to an audience. Through the written or oral mode of communication accurately and concisely.
- Self-awareness & Reflectivity - Having an awareness of your own strengths, weaknesses, aims and objectives. Able to regularly review, evaluate and reflect upon the performance of yourself and others
Subject specific skills
- Identify emerging technologies and technology trends;
- Apply underpinning concepts and ideas of engineering;
- Apply knowledge and understanding of the specialist cognate area of electronic engineering in an international context;
- Solve problems logically and systematically;
- Access and synthesize information and literature sources;
- Analyse and display data using appropriate methods and mathematical techniques;
- Use of such knowledge in modelling and design
- Problem solving strategies
- Analyse if/how a system meets current and future requirements
- Deploy theory in design, implementation and evaluation of systems
- Knowledge and/or understanding of appropriate scientific and engineering principles
- Knowledge and understanding of mathematical principles
- Knowledge and understanding of computational modelling
- Principles of appropriate supporting engineering and scientific disciplines
Resource implications for students
Recommended that they purchase the course text, but this is not essential.
Talis Reading listhttp://readinglists.bangor.ac.uk/modules/icm-3008.html
A Students Guide to Maxwell’s Equations Daniel Fleisch Cambridge Press ISBN: 978-0-521-70147-1
Schaum’s Outline of Vector Analysis Murray R Spiegal and Seymour Lipschutz McGraw-Hill ISBN: 978-0071615457
Introduction to Electrodynamics (4th Ed) David J. Griffiths Pearson ISBN: 978-1-29202-143-3
Pre- and Co-requisite Modules
Courses including this module
Compulsory in courses:
- W3H6: BA Music and Electronic Engineering year 3 (BA/MEE)
- H612: BEng Computer Systs Eng (3 yrs) year 3 (BENG/CSE)
- H61B: BEng Computer Sys Engineering (4yr with Incorp Foundation) year 3 (BENG/CSE1)
- H610: BENG Electronic Engineering (3 yrs) year 3 (BENG/ELE)
- H62B: BEng Electronic Engineering (4yr with Incorp Foundation) year 3 (BENG/ELE1)
- H61F: BEng Electronic Engineering year 3 (BENG/ELEF)
- H621: BEng Electronic Engineering with International Experience year 4 (BENG/ELEIE)
- H64B: BSc Computer Sys Engineering (4yr with Incorp Foundation) year 3 (BSC/CSE1)
- H603: BSc Computer Systems Engineering year 3 (BSC/CSENG)
- H611: BSc Electronic Engineering year 3 (BSC/ELE)
- H63B: BSc Electronic Engineering (4yr with Incorp Foundation) year 3 (BSC/ELE1)
- H661: MEng Control and Instrumentation Engineering year 3 (MENG/CIE)
- H617: MEng Computer Systs Eng (4 yrs) year 3 (MENG/CSE)
- H601: MEng Electronic Engineering (4 yrs) year 3 (MENG/EE)
- H618: MEng Electronic Engineering with International Experience year 4 (MENG/EEIE)