course: Computational Engineering 1: Fluiddynamics in electrical-engineering

number:
141377
teaching methods:
lecture with tutorials
media:
computer based presentation, black board and chalk
responsible person:
Priv.-Doz. Dr. Jürgen Geiser
lecturer:
Priv.-Doz. Dr. Jürgen Geiser (ETIT)
language:
english
HWS:
2
CP:
3
offered in:
summer term

dates in summer term

  • start:

Exam

Termin wird vom Dozenten bekannt gegeben

Form of exam:written
Registration for exam:Directly with the lecturer
Duration:60min

goals

  • Derivation of the modelling equations for fluid- and electrodynamics.
  • Introduction into numerical methods related to multiscale modells (multiscalen-methods and special discretization-methods, e.g., FDTD-methods).
  • Consolidation into special multiscale solvers, e.g., HMM (Heterogeneous Multiscale Method), EFM (Equation-Free Method), MISM (Multiscale Iterative Splitting Method).
  • Examples in the field of transport-reactions- and Maxwell-equations (e.g., particle-transport in the electromagnetic field).
  • Programming exercises in MATLAB.

content

  • Modelling of electromagnetic- and transport-problems (transport-reaction- and Maxwell-equations).
  • Preparing the theoretical principles for solving the underlying partial differential equations with different spatial- and time-scales (multiscale theory).
  • Communicating the numerical solver methods for efficient and robust simulation algorithms.
  • Communicating of so called multiscale solvers, e.g.,HMM (Heterogeneous Multiscale Methods, which allow to calculate and transfer between microscopic (fine) and macroscopic (coarse) models (or grids).
  • Introducing into commercial software-packages(MATLAB) for solving the underlying differential equations.

requirements

none

recommended knowledge

Content of the modules Mathematik 1-3

miscellaneous

The lesson will not take place in the summer term 2021.