Fritz Kretzschmar received a Student Paper Competition Award for his contribution entitled
The Discontinuous Galerkin Trefftz Method
at the 12th International Workshop on Finite Elements for Microwave Engineering (FEM2014). Coauthors are Igor Tsukerman, Thomas Weiland and myself. Congratulations!
If you are interested in more information on the time-domain DG Trefftz method have a look at our recent paper in JCAM and/or contact Fritz or me.
Pavel Solin, Pavel Karban and I edited a special issue of Journal of Computational and Applied Mathematics, which is published now as
Journal of Computational and Applied Mathematics: Volume 270 (2014)
The slides of today’s lecture on the Discontinuous Galerkin Method are available here (14 MB).
If you are interested in a project work or a bachelor/master thesis send me an email or come by.
, Igor Tsukerman
and I have a new paper in Journal of Computational Applied Mathematics (JCAM)
. The paper abstract reads
We present a novel Discontinuous Galerkin Finite Element Method for wave propagation problems. The method employs space–time Trefftz-type basis functions that satisfy the underlying partial differential equations and the respective interface boundary conditions exactly in an element-wise fashion. The basis functions can be of arbitrary high order, and we demonstrate spectral convergence in the \(L_2\)-norm. In this context, spectral convergence is obtained with respect to the approximation error in the entire space–time domain of interest, i.e. in space and time simultaneously. Formulating the approximation in terms of a space–time Trefftz basis makes high order time integration an inherent property of the method and clearly sets it apart from methods, that employ a high order approximation in space only.
My paper on error-driven dynamical hp-meshes for DG in the time-domain was accepted for publication in the Journal of Computational and Applied Mathematics. The paper abstract reads:
An hp-adaptive Discontinuous Galerkin Method for electromagnetic wave propagation phenomena in the time-domain is proposed. The method is highly efficient and allows for the first time the adaptive full-wave simulation of large, time-dependent problems in three-dimensional space. Refinement is performed anisotropically in the approximation order p and the mesh step size h regardless of the resulting level of hanging nodes. For guiding the adaptation process a variant of the concept of reference solutions with largely reduced computational costs is proposed. The computational mesh is adapted such that a given error tolerance is respected throughout the entire time-domain simulation.
For examples of dynamical hp-meshes see this post or this one. Please find the paper here on the JCAM website.
The 2013 Nobel Price in chemistry was awarded to computational chemists. I am very happy to see computational science receive the supreme honor in research.
Josip Mihaljevic, Jens Niegemann, Christian Hafner and I submitted a paper on the numerical modeling of metallic nano-tips to Quantum Matter. My contribution deals with the simulation of laser-induced electron emission from such tips. A visualization of the process is shown below.
Snapshots of electrons in an electrostatic field (not visualized) after emission from a (simplified) metallic nano-tip induced by an impinging femtosecond laser pulse.
UPDATE (Nov 3, 2013):
The paper has been accepted for publication.
The paper is available online.