Lambert Theisen


Contact

Mathematics (CCES)
RWTH Aachen University
Schinkelstr. 2
D-52062 Aachen
Germany

Room: 216a (Rogowski Building, 2nd floor)
Phone: +49 (0)241 80 98675
Email: theisen@mathcces.rwth-aachen.de


About Me


Education

  • 04/18 – 09/19: Master of Science in Computational Engineering Science (CES)
    RWTH Aachen University, Aachen, Germany
  • 10/14 – 04/18: Bachelor of Science in Computational Engineering Science (CES)
    RWTH Aachen University, Aachen, Germany


Professional

  • 10/17 – 03/18: Internship: 3D CFD Simulation and Hexahedral Meshing
    ABB Corporate Research Center Baden-Dättwil, Switzerland
  • 08/15 – 10/15: Working Student: IT and EDV Systems
    Sanofi, Frankfurt am Main, Germany
  • 07/14 – 10/14: Working Student: Export & Dispatch
    Sanofi, Frankfurt am Main, Germany


Research Interests and Projects


Domain Decomposition Methods for Electronic Structure Calculations (10/2019 – Present)

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Keywords: Electronic Structure Calculations, Domain Decomposition Methods, Preconditioned Iterative Eigensolvers


Simulation of Non-Equilibrium Gas Flows Using the FEniCS Computing Platform (Master Thesis @ MathCCES) (04/2019 – 09/2019)

This thesis provides a framework to simulate non-equilibrium gas flows using the finite element method within the FEniCS computing platform [1]. The main model equations, i.e. the R13 equations, are introduced after a motivational discussion about the classical models, given by Navier–Stokes and Fourier. The resulting system of equations is simplified to obtain a set of steady-state and linearized balance laws for two-dimensional domains.
During a validation process of the numerical method with exact solutions, particular focus is put on the intuitive implementation using the tensor capabilities of FEniCS. This allows having an almost one-to-one correspondence between the mathematical formulation and the implemented source code. A documented and validated solver is developed and can be obtained from [2]. This solver allows simulating gas flows for arbitrary shaped two-dimensional geometries using a variety of boundary conditions.
In order to justify the use of extended model equations for gas flows with moderate Knudsen number, typical examples, with occurring rarefaction effects, are presented and solved. In these application cases, the Knudsen paradox and a thermal transpiration flow are observed.

Keywords: R13 equations, FEniCS project, Non-equilibrium gas flows, Finite element method, CIP stabilization
Download: 2019_ma_lamberttheisen.pdf
References:
[1]: FEniCS Project: Bitbucket Repositories. FEniCS Project. url: https://bitbucket.org/fenics-project/ (visited on 08/28/2019).
[2]: Lambert Theisen and Manuel Torrilhon. fenicsR13: Solver Repository. RWTH Aachen University, 2019. url: https://git.rwth-aachen.de/lamBOO/fenicsR13 (visited on 09/15/2019).


Shear-Slip Mesh Update Method for Compressible Flow Simulations Involving Rotating Sub-Domains (Seminar Thesis @ CATS [1]) (11/2018 – 04/2019)

The subject of this seminar thesis is the application of the Shear-Slip Mesh Update Method (SSMUM) for compressible flow simulations. This method allows to simulate systems of moving objects, including fluid and solid regions, in an efficient way if a regular motion is assumed. Compared to other methods, the SSMUM avoids a complete remeshing of the computational domain, that is in general very computationally intensive. This is archived by a partial update of node connectivity in a special update layer between the moving and the static mesh.
The numerical method and its underlying formulation is presented in order to introduce the SSMUM. Previous applications for incompressible flows are discussed. On that basis, a first test case for compressible flows is presented. In order to generate a suitable mesh for this test case, requirements on the mesh generation step are presented and discussed.

Keywords: Shear-Slip Mesh Update Method (SSMUM), Finite Element Method, compressible flow simulation, rotating sub-domains, Deformable-Spatial-Domain/Stabilized Space-Time (DSD/SST) formulation
Download: ws18_ces_seminar_theisen.pdf
References:
[1]: CATS. url: https://www.cats.rwth-aachen.de.


Automated Boundary Layer Mesh Generation for Simulation of Convective Cooling (Bachelor Thesis @ ABB Switzerland & MathCCES) (01/2018 – 03/2018)

In 2008, a survey with simulation analysts through a wide range of disciplines presented an overall time percentage of 73% spent for meshing related tasks [1] compared to a much smaller time needed for actual simulations. For many years, the automated hexahedral meshing has been considered as the holy grail [2] within the range of mesh generation approaches, however without having definitive success for now. Compared to the relatively easy to obtain tetrahedral meshes, hexahedra based meshes allow for up to ten times less cells as stated in [2] and therefore decreasing simulation times. This thesis focuses on the meshing of arbitrary geometries in an automatic fashion using the mesh generation software snappyHexMesh provided by the open-source licensed computational fluid dynamics simulation framework OpenFOAM [3].
Within this thesis, an automated workflow based on geometry heuristics is proposed in order to generate all necessary input files for the mesh generator. The resulting meshes are then used in the context of electrothermal simulations of natural convection. The general process of heat transfer involves several mechanisms including conduction, convection and radiation. The boundary regions of the meshes, therefore, have special requirements. Luckily, snappyHexMesh provides mechanisms to also automatically insert boundary layers in these critical regions.
A study of an electrical dry transformer geometry including a large air box and very thin isolation layers acts as an industrial example to test the automatic mesh generation workflow. This test cases showed the difficulty of an automatic mesh generation for arbitrary geometries with large dimension variation resulting in a large number of cells because of the isotropic octree-based refinement approach of snappyHexMesh.

Keywords: OpenFOAM, snappyHexMesh, Automated Hexahedral Meshing, Natural Convection
Download: 2018_ba_lamberttheisen.pdf
References:
[1]: S. J. Owen et al. “An Immersive Topology Environment for Meshing”. In: Proceedings of the 16th International Meshing Roundtable. Springer, Berlin, Heidelberg, 2008, pp. 553–577. url: https://link.springer.com/chapter/10.1007/978-3-540-75103-8_31.
[2]: T. Blacker. “Automated Conformal Hexahedral Meshing Constraints, Challenges and Opportunities”. In: Engineering with Computers 17.3 (2001), pp. 201–210. url: https://link.springer.com/article/10.1007/PL00013384.
[3]: H. G. Weller et al. “A tensorial approach to computational continuum mechanics using object-oriented techniques”. In: Computers in Physics 12.6 (1998), pp. 620–631. url: http://powerlab.fsb.hr/ped/kturbo/OpenFOAM/docs/Foam.pdf.


Supervised Work

  • Using a Spectral Inference Network to Solve the Time-Independent Schrödinger Equation for a Two-Dimensional Hydrogen Atom, Seminar Thesis of Alexander Kristof, RWTH Aachen, 2020.


Teaching

  • WS19/20: Mathematische Grundlagen I (CES) @ MathCCES, RWTH Aachen
  • SS19: Mathematische Grundlagen IV (CES) @ MathCCES, RWTH Aachen
  • WS18/19: Partielle Differentialgleichungen (CES) @ MathCCES, RWTH Aachen


Publications

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Talks

  • Simulation of Non-Equilibrium Gas Flows Using the FEniCS Computing Platform, Master Thesis Defense, RWTH Aachen, 15 October, 2019 .
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Student Projects

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TODO

  • Add supervisors with hyperlinks

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Last modified:: 2020/02/19 11:27