|| PH32510 |
|| ELECTROMAGNETISM |
|| 2004/2005 |
|| Dr Eleri Pryse |
|| Semester 1 |
|| Dr Xing Li |
|| Core Physics Modules at Levels 1 & 2 |
| Course delivery
|| Lecture || 20 lectures |
|Assessment Type||Assessment Length/Details||Proportion|
|Semester Exam||2 Hours end of semester examination for BSc students ||80%|
|Semester Exam||3 Hours end of semester examination for MPhys students ||80%|
|Semester Assessment|| Course Work: Two examples sheets by Semester week 7 and Semester week 11 ||20%|
After taking this module students should be able to:
apply the differential operators of vector calculus to electromagnetic problems.
describe the four basic laws of electromagnetism and their applications.
explain the effects of matter on electric and magnetic fields and the boundary conditions for such fields.
solve problems on resonance in alternating current circuits.
describe the basic properties of transmission lines for the propagation of electrical signals.
This module builds on the foundations laid in PH125020, and presents the concepts of electromagnetism introduced in the earlier module in terms of vector calculus. Topics covered include electrostatics, dielectrics, magnetic fields, magnetic fields in matter, electromagnetic induction, alternating currents and resonance, transmission lines, Maxwell's equations.
Recap, grad, div, curl, divergence theorem, Stokes' theorem, vector identities.
Electric charge and field, Gauss' law in differential form, electrostatic energy, potential, capacitors, dielectrics, polarisation, electric displacement, boundary conditions for D and E, Poisson's equation, electrostatic calculations.
Lorentz force, magnetic dipole, Ampere's law in differential form, magnetic vector potential, Biot-Savart law, magnetic flux, magnetisation, magnetic intensity, boundary conditions for B and H, hysteresis.
Faraday's law in differential form, inductance, magnetic energy.
Wave propagation on lossless line, practical lines, reflections, input impedance, matching.
Equation of continuity, displacement current, Maxwell's equations.
Grant & Phillips Electromagnetism
2nd. ISBN 0471-92712-0
This module is at CQFW Level 6