Course
TED - Theoretical Electro Dynamics
PDF Course Catalog Deutsche Version: TED
Version: 5 | Last Change: 02.11.2019 16:14 | Draft: 0 | Status: vom verantwortlichen Dozent freigegeben
| Long name | Theoretical Electro Dynamics |
|---|---|
| Approving CModule | TED_MaET |
| Responsible |
Prof. Dr. Karl Kohlhof
Professor Fakultät IME |
| Level | Master |
| Semester in the year | summer semester |
| Duration | Semester |
| Hours in self-study | 78 |
| ECTS | 5 |
| Professors |
Prof. Dr. Karl Kohlhof
Professor Fakultät IME |
| Requirements | Vector analysis |
| Language | German |
| Separate final exam | Yes |
Literature
Lehner: "Elektromagnetische feldtheorie für Ingenieure", Springer-Verlag
Wunsch: "Elektromagnetische Felder", Verlag technik
Wunsch: "Elektromagnetische Felder", Verlag technik
Final exam
Details
normally written ( low number of candidates: oral)Minimum standard
grade 4.0Exam Type
normally written ( low number of candidates: oral)Learning goals
Knowledge
Introduction into Electro Dynamics
Charges, currents
Forces, fields
Classical Electro Dynamics
Electrostatics
Field, potential
Polarization
Electrostatic energy
Capacity
Multi pole development
Interaction of charge distributions
Stationary electrical field
Magnetostatics
Stationary magnetical field
Vector potential
Magnetization
Magetostatic energy
Inductivity
Quasi stationary electromagnetic fields
Induction effects
Skin effect
Rapidly changing electromagetic fields
Electromagnetic wves
Reflection and diffraction
Charges, currents
Forces, fields
Classical Electro Dynamics
Electrostatics
Field, potential
Polarization
Electrostatic energy
Capacity
Multi pole development
Interaction of charge distributions
Stationary electrical field
Magnetostatics
Stationary magnetical field
Vector potential
Magnetization
Magetostatic energy
Inductivity
Quasi stationary electromagnetic fields
Induction effects
Skin effect
Rapidly changing electromagetic fields
Electromagnetic wves
Reflection and diffraction
Skills
Knowledge of meaning of Maxwell- and material equations
Dervation of electric/magnetic potential/field from charge/current distributions
Development of potential / field to monopole, dipole, quadrupole and higher moments
Caculation of capacity/inductivity to charge/current distributions from energy balance
Derivation of Continuity equation, Kirschhoff Laws from Maxwell equations
Derivation and solving of diffusion/wave equations from Maxwell equations
Solving of macroscopic problems by intergation of microscopic/differential description
Solving of training examples
Dervation of electric/magnetic potential/field from charge/current distributions
Development of potential / field to monopole, dipole, quadrupole and higher moments
Caculation of capacity/inductivity to charge/current distributions from energy balance
Derivation of Continuity equation, Kirschhoff Laws from Maxwell equations
Derivation and solving of diffusion/wave equations from Maxwell equations
Solving of macroscopic problems by intergation of microscopic/differential description
Solving of training examples
Expenditure classroom teaching
| Type | Attendance (h/Wk.) |
|---|---|
| Lecture | 3 |
| Exercises (whole course) | 1 |
| Exercises (shared course) | 0 |
| Tutorial (voluntary) | 0 |
Special literature
keine/none
Special requirements
Mathematics, Linear algebra, Vetor analysis
Accompanying material
electronic pdf script of lecture/presentation
electronic pdf file with training examples
electronic pdf file with training examples
Separate exam
none
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