Handbook 1996 : Faculty of Science (Volume 4 page 228)
Physics subject : Next:640-246 | Prev:640-243 | Search | Help
640-245 "Electromagnetism" appears differently in several places - choose the one you want:
1. Physics, Faculty of Science (v4, p228) : Next:640-246 | Prev:640-243
Credit points: 6.0
Coordinator: Dr F. di Marzio
Prerequisite: Physics 640-121+122 or 141+142 (before 1996: 640-120 or 640-140): Mathematics 618-121 or 618-142 (before 1996: 618-101); Mathematics 618-122 or 618-200 or 618-211 (before 1996: 618-102); Mathematics 618-132 or 618-130.
Pre/Corequisite: Mathematics 618-231
Contact: 18 lectures (two hours a week) and eight 1-hour tutorials
Timetable: Second semester
Objectives:
By the completion of this course the student should:
- comprehend how Maxwell's equations provide a unified understanding of electrical, magnetic and optical phenomena;
- be able to apply Maxwell's equation to simple problems, including those involving dielectric and magnetic media;
- appreciate the key role that Maxwell's equations play in a wide range of science and engineering.
Content:
Maxwell's equations in differential form. Scalar and vector potentials. Dielectric and magnetic materials: field vectors P, D, M, H. Boundary conditions for field vectors. Magnetic circuits. Energy density of electric and magnetic fields. Simple boundary value problems. Electromagnetic waves: in vacuum and simple dielectrics; wave equations; Poynting's vector.
Assessment:
A 2-hour end-of-semester written examination
Prescribed texts:
1. Physics, Faculty of Science (v4, p228) : Next:640-246 | Prev:640-243
2. Physics, Faculty of Educ(Parkville) (v5, p158) : Next:640-246 | Prev:640-243
Credit points: 6.0
Coordinator: Dr F di Marzio.
Prerequisite: Physics 640-121+122 or 141+142 (before 1996: 640-120 or 640-140): Mathematics 618-121 or 618-142 (before 1996: 618-101); Mathematics 618-122 or 618-200 or 618-211 (before 1996: 618-102); Mathematics 618-132 or 618-130.
Pre/Corequisite: Mathematics 618-231.
Contact: 18 lectures (two hours a week) and eight 1-hour tutorials
Timetable: Second semester.
Objectives:
By the completion of this course the student should:
- comprehend how Maxwell's equations provide a unified understanding of electrical, magnetic and optical phenomena;
- be able to apply Maxwell's equation to simple problems, including those involving dielectric and magnetic media;
- appreciate the key role that Maxwell's equations play in a wide range of science and engineering.
Content:
Maxwell's equations in differential form. Scalar and vector potentials. Dielectric and magnetic materials: field vectors P, D, M, H. Boundary conditions for field vectors. Magnetic circuits. Energy density of electric and magnetic fields. Simple boundary value problems. Electromagnetic waves: in vacuum and simple dielectrics; wave equations; Poynting's vector.
Assessment:
A 2-hour end-of-semester written examination
Prescribed texts:
* Note that COORDINATOR, PREREQUISITES, PRESCRIBEDTEXTS differs from the maintainer's version above. A log of variations is available.
2. Physics, Faculty of Educ(Parkville) (v5, p158) : Next:640-246 | Prev:640-243
Status: Official 1996 Date created: Oct 9 1995 Last modified: Oct 9 1995 Authorised by: Academic Registrar Email enquiries: Course_Information@registrar.unimelb.edu.au
Maintained by: School of Physics, Faculty of Science.
Copyright © University of Melbourne 1995,1996.