After finishing the course, students will be able to present and explain the basics of electromagnetic field theorie. They can differentiate between integrated and local representation and argue for the more general aplicability of the local representation in form of differential equations. They are aware of the prerequisites for the simplification of equations and have the tools to judge their aplicability for given problems. They can calculate the fields resulting from given sources and sinks. They can present the reaction of matter to an electromagnetic field and derive the macroscopic maxwell equations from their microscopic counterparts. They can apply those equations inside matter and on surface areas. They can calculate the propagation of a plane wave and it's interaction with matter in simple geometries. They can find strategies to solve elementary problems.
Practice
Contacts
The practices for the lecture Grundlagen der elektromagnetischen Feldtheorie are supervised by Björn Neubauer, Lukas Oppermann and Altan Akar.
Material is provided on Stud.IP at the lecture in the section 'Dateien'.
Exam
Writen exam of 120 minutes or oral exam of 30 minutes.
Material
Script for the lecture:
Basistext ElektromagnetischeFelder
Please be aware of the information given in the first lecture. For more information: here.
Students will be able analyse basic electronic devices using field theory and abstract them into a simpler form. They can choose and execute strategies for solving for example energetic problems, the poynting-theorem or temporal and spacial variable fields.
Practice
Contacts
The practices for the lecture Grundlagen der elektromagnetischen Feldtheorie are supervised by Björn Neubauer, Lukas Oppermann and Altan Akar.
Material is provided on Stud.IP at the lecture in the section 'Dateien'.
Exam
Writen exam of 120 minutes or oral exam of 30 minutes.
Material
Script for the lecture:
Basistext ElektromagnetischeFelder
Please be aware of the information given in the first lecture. For more information: here.
Terms and definitions - Sources and measurements of interference - Interactions: galvanic, capacitive, inductive interactions, wave and radiation interactions - Interference immunity of interference sinks - Achieving EMC by measures taken at the source of interference, at the way of interaction and at the interference sink - Dampening and surge protection - EMC testing - electromagnetic compatability of biological systems
Content Of Practice
In the practice multiple illustrative examples of practical EMC problems are presented and calculated using the methods provided in the lecture.
Assignments will be handed out during the practice.
Exam
Times of oral exams are available at the institute blackboard.
Duration: About 30 minutes.
Consultation appointments can be sheduled on short notice via telephone or email.
This lecture will not be offered until further notice. The topics mainly covered in the numerical analysis are also taught in the module “Electromagnetic Theory for High Frequency Technology” by Prof. Jörg Schöbel.
