|
|
|
||
Last update: RNDr. Martin Veis, Ph.D. (07.06.2019)
To introduce the students advanced numerical methods for solution of selected problems in electromagnetism. |
|
||
Last update: RNDr. Martin Veis, Ph.D. (07.06.2019)
oral exam |
|
||
Last update: RNDr. Martin Veis, Ph.D. (07.06.2019)
[1] A. Tafloe, Computational electrodynamics, The Finite-Difference Time-Domain Method, Artech House, 1995 [2] J. D. Jackson, Classical Electrodynamics, John Wiley,1999 [3] J. N. Reddy, Introduction to the Finite Element Method, McGraw-Hill, 1993 |
|
||
Last update: RNDr. Martin Veis, Ph.D. (07.06.2019)
knowledge of the topics explained during lectures |
|
||
Last update: RNDr. Martin Veis, Ph.D. (07.06.2019)
1. Method of Moments Integral form of Maxwell equations, Method of Weighted Residuals, Galerkin Method, RWG base functions. 2. Finite Element Method (FEM) Discretization, variation approach, solution of selected 1D and 2D problems. 3. Finite Difference methods in Frequency (FDFD) and Time (FDTD) Domains Discretization, “leapfrog” algorithm, solution of Maxwell equations, Courrant condition of numerical stability, boundary conditions. 4. Fourier Modal Method (FMM) Periodic boundary conditions, expansion into eigenmodes by using methods of linear algebra. |