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ORCIDStefan Turek
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- affiliation: TU Dortmund University, Germany
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2020 – today
- 2024
[j42]Katharina Wegener, Dmitri Kuzmin, Stefan Turek:
Efficient numerical solution of the Fokker-Planck equation using physics-conforming finite element methods. J. Num. Math. 32(3): 217-232 (2024)- 2022
- [j41]Dustin Ruda
, Stefan Turek, Dirk Ribbrock, Peter Zajac:
Very fast finite element Poisson solvers on lower precision accelerator hardware: A proof of concept study for Nvidia Tesla V100. Int. J. High Perform. Comput. Appl. 36(4): 459-474 (2022) - [j40]Christoph Lohmann, Jonas Dünnebacke, Stefan Turek:
Fourier analysis of a time-simultaneous two-grid algorithm using a damped Jacobi waveform relaxation smoother for the one-dimensional heat equation. J. Num. Math. 30(3): 173-207 (2022) - 2021
- [j39]Jonas Dünnebacke, Stefan Turek, Christoph Lohmann, Andriy Sokolov, Peter Zajac:
Increased space-parallelism via time-simultaneous Newton-multigrid methods for nonstationary nonlinear PDE problems. Int. J. High Perform. Comput. Appl. 35(3) (2021) - 2020
- [p6]Peter Bastian, Mirco Altenbernd, Nils-Arne Dreier, Christian Engwer, Jorrit Fahlke, René Fritze, Markus Geveler, Dominik Göddeke, Oleg Iliev, Olaf Ippisch, Jan Mohring, Steffen Müthing, Mario Ohlberger, Dirk Ribbrock, Nikolay Shegunov, Stefan Turek:
Exa-Dune - Flexible PDE Solvers, Numerical Methods and Applications. Software for Exascale Computing 2020: 225-269
2010 – 2019
- 2019
- [j38]Andriy Sokolov, Oleg Davydov, Dmitri Kuzmin, Alexander Westermann, Stefan Turek:
A flux-corrected RBF-FD method for convection dominated problems in domains and on manifolds. J. Num. Math. 27(4): 253-269 (2019) - [c15]Jonas Dünnebacke, Stefan Turek, Peter Zajac, Andriy Sokolov:
A Time-Simultaneous Multigrid Method for Parabolic Evolution Equations. ENUMATH 2019: 333-342 - [c14]Hannes Ruelmann, Markus Geveler, Dirk Ribbrock, Peter Zajac, Stefan Turek:
Basic Machine Learning Approaches for the Acceleration of PDE Simulations and Realization in the FEAT3 Software. ENUMATH 2019: 449-457 - [c13]Dustin Ruda, Stefan Turek, Peter Zajac, Dirk Ribbrock:
The Concept of Prehandling as Direct Preconditioning for Poisson-Like Problems. ENUMATH 2019: 1011-1019 - [c12]Patrick Westervoß, Stefan Turek:
Simulating Two-Dimensional Viscoelastic Fluid Flows by Means of the "Tensor Diffusion" Approach. ENUMATH 2019: 1167-1175 - [i1]Peter Bastian, Mirco Altenbernd, Nils-Arne Dreier, Christian Engwer, Jorrit Fahlke, René Fritze, Markus Geveler, Dominik Göddeke, Oleg Iliev, Olaf Ippisch, Jan Mohring, Steffen Müthing, Mario Ohlberger, Dirk Ribbrock, Nikolay Shegunov, Stefan Turek:
Exa-Dune - Flexible PDE Solvers, Numerical Methods and Applications. CoRR abs/1911.01492 (2019) - 2018
- [j37]Alexander Schwarz, Masoud Nickaeen, Serdar Serdas, Carina Nisters, Abderrahim Ouazzi, Jörg Schröder, Stefan Turek:
A comparative study of mixed least-squares FEMs for the incompressible Navier-Stokes equations. Int. J. Comput. Sci. Eng. 17(1): 80-97 (2018) - 2017
- [j36]Mohammad Amin Safi, Nikolaos Prasianakis, Stefan Turek:
Benchmark computations for 3D two-phase flows: A coupled lattice Boltzmann-level set study. Comput. Math. Appl. 73(3): 520-536 (2017) - [j35]Babak S. Hosseini, Stefan Turek, Matthias Möller, Christian Palmes:
Isogeometric Analysis of the Navier-Stokes-Cahn-Hilliard equations with application to incompressible two-phase flows. J. Comput. Phys. 348: 171-194 (2017) - 2016
- [j34]Markus Geveler, Balthasar Reuter, Vadym Aizinger, Dominik Göddeke, Stefan Turek:
Energy efficiency of the simulation of three-dimensional coastal ocean circulation on modern commodity and mobile processors. Comput. Sci. Res. Dev. 31(4): 225-234 (2016) - [c11]Markus Geveler, Dirk Ribbrock, Daniel Donner, Hannes Ruelmann, Christoph Höppke, David Schneider, Daniel Tomaschewski, Stefan Turek:
The ICARUS White Paper: A Scalable, Energy-Efficient, Solar-Powered HPC Center Based on Low Power GPUs. Euro-Par Workshops 2016: 737-749 - [p5]Peter Bastian, Christian Engwer, Jorrit Fahlke, Markus Geveler, Dominik Göddeke, Oleg P. Iliev, Olaf Ippisch, René Milk, Jan Mohring, Steffen Müthing, Mario Ohlberger, Dirk Ribbrock, Stefan Turek:
Hardware-Based Efficiency Advances in the EXA-DUNE Project. Software for Exascale Computing 2016: 3-23 - [p4]Peter Bastian, Christian Engwer, Jorrit Fahlke, Markus Geveler, Dominik Göddeke, Oleg P. Iliev, Olaf Ippisch, René Milk, Jan Mohring, Steffen Müthing, Mario Ohlberger, Dirk Ribbrock, Stefan Turek:
Advances Concerning Multiscale Methods and Uncertainty Quantification in EXA-DUNE. Software for Exascale Computing 2016: 25-43 - 2015
- [j33]Babak S. Hosseini, Matthias Möller, Stefan Turek:
Isogeometric Analysis of the Navier-Stokes equations with Taylor-Hood B-spline elements. Appl. Math. Comput. 267: 264-281 (2015) - [j32]Mohammad Amin Safi, Stefan Turek:
Efficient computations for high density ratio rising bubble flows using a diffused interface, coupled lattice Boltzmann-level set scheme. Comput. Math. Appl. 70(6): 1290-1305 (2015) - [j31]Johan Shu-Ren Hysing, Stefan Turek:
Evaluation of commercial and academic CFD codes for a two-phase flow benchmark test case. Int. J. Comput. Sci. Eng. 10(4): 387-394 (2015) - [j30]Andriy Sokolov, Ramzan Ali, Stefan Turek:
An AFC-stabilized implicit finite element method for partial differential equations on evolving-in-time surfaces. J. Comput. Appl. Math. 289: 101-115 (2015) - [c10]Saptarshi Mandal, Abderrahim Ouazzi, Stefan Turek:
Modified Newton Solver for Yield Stress Fluids. ENUMATH 2015: 481-490 - 2014
- [j29]Masoud Nickaeen, Abderrahim Ouazzi, Stefan Turek:
Newton multigrid least-squares FEM for the V-V-P formulation of the Navier-Stokes equations. J. Comput. Phys. 256: 416-427 (2014) - [j28]Thomas Hübner, Rashid Mahmood, Stefan Turek:
Fully implicit nonstationary flow simulations with a monolithic off-lattice Boltzmann approach. J. Num. Math. 22(2): 143-164 (2014) - [c9]Peter Bastian, Christian Engwer, Dominik Göddeke, Oleg Iliev, Olaf Ippisch, Mario Ohlberger, Stefan Turek, Jorrit Fahlke, Sven Kaulmann, Steffen Müthing, Dirk Ribbrock:
EXA-DUNE: Flexible PDE Solvers, Numerical Methods and Applications. Euro-Par Workshops (2) 2014: 530-541 - 2013
- [j27]Frank Weichert, Lars Walczak, Denis Fisseler, Tobias Opfermann, Mudassar Razzaq, Raphael Münster, Stefan Turek, Iris Grunwald, Christian Roth, Christian Veith, Mathias Wagner:
Simulation of Intra-Aneurysmal Blood Flow by Different Numerical Methods. Comput. Math. Methods Medicine 2013: 527654:1-527654:10 (2013) - [j26]Robert Strehl, Andriy Sokolov, Dmitri Kuzmin, Dirk Horstmann, Stefan Turek:
A positivity-preserving finite element method for chemotaxis problems in 3D. J. Comput. Appl. Math. 239: 290-303 (2013) - [c8]Abderrahim Ouazzi, Masoud Nickaeen, Stefan Turek, Muhammad Waseem:
Newton-Multigrid Least-Squares FEM for S-V-P Formulation of the Navier-Stokes Equations. ENUMATH 2013: 651-659 - [c7]Hogenrich Damanik, Abderrahim Ouazzi, Stefan Turek:
Numerical Simulation of Polymer Film Stretching. ENUMATH 2013: 709-716 - 2012
- [j25]Robert Strehl, Andriy Sokolov, Stefan Turek:
Efficient, accurate and flexible finite element solvers for chemotaxis problems. Comput. Math. Appl. 64(3): 175-189 (2012) - [j24]Evren Bayraktar, Otto Mierka, Stefan Turek:
Benchmark computations of 3D laminar flow around a cylinder with CFX, OpenFOAM and FeatFlow. Int. J. Comput. Sci. Eng. 7(3): 253-266 (2012) - [p3]Michael Hinze, Michael Köster, Stefan Turek:
A Space-Time Multigrid Method for Optimal Flow Control. Constrained Optimization and Optimal Control for Partial Differential Equations 2012: 147-170 - 2011
- [j23]Evren Bayraktar, Otto Mierka, F. Platte, Dmitri Kuzmin, Stefan Turek:
Numerical aspects and implementation of population balance equations coupled with turbulent fluid dynamics. Comput. Chem. Eng. 35(11): 2204-2217 (2011) - [j22]Marcel Gurris, Dmitri Kuzmin, Stefan Turek:
Implicit finite element schemes for stationary compressible particle-laden gas flows. J. Comput. Appl. Math. 235(17): 5056-5077 (2011) - [j21]Shafqat Hussain, Friedhelm Schieweck, Stefan Turek:
Higher order Galerkin time discretizations and fast multigrid solvers for the heat equation. J. Num. Math. 19(1): 41-61 (2011) - 2010
- [j20]Robert Strehl, Andriy Sokolov, Dmitri Kuzmin, Stefan Turek:
A Flux-Corrected Finite Element Method for Chemotaxis Problems. Comput. Methods Appl. Math. 10(2): 219-232 (2010) - [j19]Thomas Hübner, Stefan Turek:
Efficient monolithic simulation techniques for the stationary Lattice Boltzmann equation on general meshes. Comput. Vis. Sci. 13(3): 129-143 (2010) - [j18]Stefan Turek, Dominik Göddeke, Christian Becker, Sven H. M. Buijssen, Hilmar Wobker:
FEAST - realization of hardware-oriented numerics for HPC simulations with finite elements. Concurr. Comput. Pract. Exp. 22(16): 2247-2265 (2010) - [j17]Marcel Gurris, Dmitri Kuzmin, Stefan Turek:
Finite element simulation of compressible particle-laden gas flows. J. Comput. Appl. Math. 233(12): 3121-3129 (2010) - [c6]Markus Geveler, Dirk Ribbrock, Dominik Göddeke, Stefan Turek:
Lattice-Boltzmann Simulation of the Shallow-Water Equations with Fluid-Structure Interaction on Multi- and Manycore Processors. Facing the Multicore-Challenge 2010: 92-104 - [c5]Dirk Ribbrock, Markus Geveler, Dominik Göddeke, Stefan Turek:
Performance and accuracy of Lattice-Boltzmann kernels on multi- and manycore architectures. ICCS 2010: 239-247 - [p2]Stefan Turek, Dominik Göddeke, Sven H. M. Buijssen, Hilmar Wobker:
Hardware-Oriented Multigrid Finite Element Solvers on GPU-Accelerated Clusters. Scientific Computing with Multicore and Accelerators 2010: 113-130
2000 – 2009
- 2009
- [j16]Dominik Göddeke, Hilmar Wobker, Robert Strzodka, Jamaludin Mohd-Yusof, Patrick S. McCormick, Stefan Turek:
Co-processor acceleration of an unmodified parallel solid mechanics code with FEASTGPU. Int. J. Comput. Sci. Eng. 4(4): 254-269 (2009) - [j15]Hogenrich Damanik, Jaroslav Hron, Abderrahim Ouazzi, Stefan Turek:
A monolithic FEM-multigrid solver for non-isothermal incompressible flow on general meshes. J. Comput. Phys. 228(10): 3869-3881 (2009) - [j14]Matthias Grajewski, Michael Köster, Stefan Turek:
Mathematical and Numerical Analysis of a Robust and Efficient Grid Deformation Method in the Finite Element Context. SIAM J. Sci. Comput. 31(2): 1539-1557 (2009) - [c4]Dominik Göddeke, Sven H. M. Buijssen, Hilmar Wobker, Stefan Turek:
GPU acceleration of an unmodified parallel finite element Navier-Stokes solver. HPCS 2009: 12-21 - 2008
- [j13]Dominik Göddeke, Robert Strzodka, Jamaludin Mohd-Yusof, Patrick S. McCormick, Hilmar Wobker, Christian Becker, Stefan Turek:
Using GPUs to improve multigrid solver performance on a cluster. Int. J. Comput. Sci. Eng. 4(1): 36-55 (2008) - [p1]Sven H. M. Buijssen, Hilmar Wobker, Dominik Göddeke, Stefan Turek:
FEASTSolid and FEASTFlow: FEM Applications Exploiting FEAST's HPC Technologies. High Performance Computing in Science and Engineering 2008: 425-440 - 2007
- [j12]Thomas Hübner, Stefan Turek:
An efficient and accurate short-characteristics solver for radiative transfer problems. Computing 81(4): 281-296 (2007) - [j11]Dmitri Kuzmin, Otto Mierka, Stefan Turek:
On the implementation of the κ-ε turbulence model in incompressible flow solvers based on a finite element discretisation. Int. J. Comput. Sci. Math. 1(2/3/4): 193-206 (2007) - [j10]Decheng Wan, Stefan Turek:
Fictitious boundary and moving mesh methods for the numerical simulation of rigid particulate flows. J. Comput. Phys. 222(1): 28-56 (2007) - [j9]Stefan Turek, Abderrahim Ouazzi:
Unified edge-oriented stabilization of nonconforming FEM for incompressible flow problems: Numerical investigations. J. Num. Math. 15(4): 299-322 (2007) - [j8]Dominik Göddeke, Robert Strzodka, Stefan Turek:
Performance and accuracy of hardware-oriented native-, emulated- and mixed-precision solvers in FEM simulations. Int. J. Parallel Emergent Distributed Syst. 22(4): 221-256 (2007) - [j7]Dominik Göddeke, Robert Strzodka, Jamaludin Mohd-Yusof, Patrick S. McCormick, Sven H. M. Buijssen, Matthias Grajewski, Stefan Turek:
Exploring weak scalability for FEM calculations on a GPU-enhanced cluster. Parallel Comput. 33(10-11): 685-699 (2007) - 2006
- [j6]Stefan Turek, Christian Becker, Susanne Kilian:
Hardware-oriented numerics and concepts for PDE software. Future Gener. Comput. Syst. 22(1-2): 217-238 (2006) - [j5]Stefan Turek, Liudmila Rivkind, Jaroslav Hron, Roland Glowinski:
Numerical Study of a Modified Time-Stepping theta-Scheme for Incompressible Flow Simulations. J. Sci. Comput. 28(2-3): 533-547 (2006) - 2002
- [j4]Stefan Turek, Abderrahim Ouazzi, Rainer Schmachtel:
Multigrid methods for stabilized nonconforming finite elements for incompressible flow involving the deformation tensor formulation. J. Num. Math. 10(3): 235-248 (2002) - [c3]Sven H. M. Buijssen, Stefan Turek:
Sources of Parallel Inefficiency for Incompressible CFD Simulations (Research Note). Euro-Par 2002: 701-704
1990 – 1999
- 1999
- [b1]Stefan Turek:
Efficient Solvers for Incompressible Flow Problems - An Algorithmic and Computational Approach. Lecture Notes in Computational Science and Engineering 6, Springer 1999, ISBN 978-3-642-63573-1, pp. I-XV, 1-358 - [j3]Stefan Turek, Christian Becker, A. Runge:
Performance Rating via the Feast Indices. Computing 63(3): 283-297 (1999) - [c2]Christian Becker, Susanne Kilian, Stefan Turek:
Consequences of Modern Hardware Design for Numerical Simulations and Their Realization in FEAST. Euro-Par 1999: 643-650 - 1998
- [c1]Christian Becker, Susanne Kilian, Stefan Turek:
Some Concepts of the Software Package FEAST. VECPAR 1998: 271-284 - 1995
- [j2]Stefan Turek:
A Generalized Mean Intensity Approach for the Numerical Solution of the Radiative Transfer Equation. Computing 54(1): 27-38 (1995) - 1993
- [j1]Stefan Turek:
An Efficient Solution Technique for the Radiative Transfer Equation. IMPACT Comput. Sci. Eng. 5(3): 201-214 (1993)
Coauthor Index
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