Alexander Heinlein

TU Delft

DIAM, Faculty of EEMCS

Numerical Analysis

Mekelweg 4, 2628 CD Delft

Room HB 03.290

Tel.: +31 (0)15 27 89135

Alexander Heinlein is assistant professor in the Numerical Analysis group of the Delft Institute of Applied Mathematics (DIAM), Faculty of Electrical Engineering, Mathematics & Computer Science (EEMCS), at the Delft University of Technology (TU Delft).

His main research areas are numerical methods for partial differential equations and scientific computing, in particular, solvers and discretizations based on domain decomposition and multiscale approaches. He is interested in high-performance computing (HPC) and solving challenging problems involving, e.g., complex geometries, highly heterogenous coefficient functions, or the coupling of multiple physics. More recently, Alexander also started focusing on the combination of scientific computing and machine learning, a new research area also known as scientific machine learning (SciML). Generally, his work includes the development of new methods and their theoretical foundation as well as their implementation on current computer architectures (CPUs, GPUs) and application to real world problems.

news

Jan 17, 2022	New open master project, co-supervised by Edo Frederix (NRG) and Deepesh Toshniwal (TU Delft, Numerical Analysis), available; see thesis projects.
Dec 20, 2021	New open master project, co-supervised by Carolin Mehlmann (Max-Planck-Institute of Meteorology), available; see thesis projects.
Nov 20, 2021	Presentation about FROSch preconditioners for land ice simulations of Greenland and Antarctica at the Trilinos User-Developer Group Meeting 2021.

recent publications (full list)

PAMM
On temporal homogenization in the numerical simulation of atherosclerotic plaque growth

Frei, Stefan, Heinlein, Alexander, and Richter, Thomas

In PAMM 2021

Abstract Bib doi HTML Preprint

A temporal homogenization approach for the numerical simulation of atherosclerotic plaque growth is extended to fully coupled fluid-structure interaction (FSI) simulations. The numerical results indicate that the two-scale approach yields significantly different results compared to a simple heuristic averaging, where only stationary long-scale FSI problems are solved, confirming the importance of incorporating stress variations on small time-scales. In the homogenization approach, a periodic fine-scale problem, which is periodic with respect to the heart beat, has to be solved for each long-scale time step. Even if no exact initial conditions are available, periodicity can be achieved within only 2–3 heart beats by simple time-stepping.
@inproceedings{Frei:2021:THN, author = {Frei, Stefan and Heinlein, Alexander and Richter, Thomas}, title = {On temporal homogenization in the numerical simulation of atherosclerotic plaque growth}, booktitle = {PAMM}, volume = {21}, number = {1}, pages = {e202100055}, year = {2021}, doi = {10.1002/pamm.202100055}, abbr = {PAMM}, url = {https://onlinelibrary.wiley.com/doi/10.1002/pamm.202100055}, preprint = {https://arxiv.org/abs/2106.09394}, keywords = {published, recent}, bibtex_show = {true} }
SISC
FROSch Preconditioners for Land Ice Simulations of Greenland and Antarctica

Heinlein, Alexander, Perego, Mauro, and Rajamanickam, Sivasankaran

Accepted for publication in SIAM Journal on Scientific Computing. January 2022

Abstract Bib Preprint

Numerical simulations of Greenland and Antarctic ice sheets involve the solution of large-scale highly nonlinear systems of equations on complex shallow geometries. This work is concerned with the construction of Schwarz preconditioners for the solution of the associated tangent problems, which are challenging for solvers mainly because of the strong anisotropy of the meshes and wildly changing boundary conditions that can lead to poorly constrained problems on large portions of the domain. Here, two-level GDSW (Generalized Dryja-Smith-Widlund) type Schwarz preconditioners are applied to diﬀerent land ice problems, i.e., a velocity problem, a temperature problem, as well as the coupling of the former two problems. We employ the MPI-parallel implementation of multi-level Schwarz preconditioners provided by the package FROSch (Fast and Robust Schwarz) from the Trilinos library. The strength of the proposed preconditioner is that it yields out-of-the-box scalable and robust preconditioners for the single physics problems. To our knowledge, this is the ﬁrst time two-level Schwarz preconditioners are applied to the ice sheet problem and a scalable preconditioner has been used for the coupled problem. The preconditioner for the coupled problem diﬀers from previous monolithic GDSW preconditioners in the sense that decoupled extension operators are used to compute the values in the interior of the subdomains. Several approaches for improving the performance, such as reuse strategies and shared memory OpenMP parallelization, are explored as well. In our numerical study we target both uniform meshes of varying resolution for the Antarctic ice sheet as well as non uniform meshes for the Greenland ice sheet are considered. We present several weak and strong scaling studies conﬁrming the robustness of the approach and the parallel scalability of the FROSch implementation. Among the highlights of the numerical results are a weak scaling study for up to 32 K processor cores (8 K MPI-ranks and 4 OpenMP threads) and 566 M degrees of freedom for the velocity problem as well as a strong scaling study for up to 4 K processor cores (and MPI-ranks) and 68 M degrees of freedom for the coupled problem.
@techreport{Heinlein:2022:FRO, author = {Heinlein, Alexander and Perego, Mauro and Rajamanickam, Sivasankaran}, title = {FROSch Preconditioners for Land Ice Simulations of Greenland and Antarctica}, note = {Accepted for publication in SIAM Journal on Scientific Computing. January 2022}, abbr = {SISC}, preprint = {https://kups.ub.uni-koeln.de/id/eprint/30668}, keywords = {accepted, reviewed, selected, recent}, bibtex_show = {true} }
ETNA
Surrogate Convolutional Neural Network Models for Steady Computational Fluid Dynamics Simulations

Eichinger, Matthias, Heinlein, Alexander, and Klawonn, Axel

Accepted for publication in ETNA. October 2021.

Abstract Bib Preprint

A convolution neural network (CNN)-based approach for the construction of reduced order surrogate models for computational fluid dynamics (CFD) simulations is introduced; it is inspired by the approach of Guo, Li, and Iori [X. Guo, W. Li, and F. Iorio, Convolutional neural networks for steady flow approximation, in Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, KDD’16, New York, USA, 2016, ACM, pp. 481–490]. In particular, the neural networks are trained in order to predict images of the flow field in a channel with varying obstacle based on an image of the geometry of the channel. A classical CNN with bottleneck structure and a U-Net are compared while varying the input format, the number of decoder paths, as well as the loss function used to train the networks. This approach yields very low prediction errors, in particular, when using the U-Net architecture. Furthermore, the models are also able to generalize to unseen geometries of the same type. A transfer learning approach enables the model to be trained to a new type of geometries with very low training cost. Finally, based on this transfer learning approach, a sequential learning strategy is introduced, which significantly reduces the amount of necessary training data.
@techreport{Eichinger:2021:SCN, author = {Eichinger, Matthias and Heinlein, Alexander and Klawonn, Axel}, title = {Surrogate Convolutional Neural Network Models for Steady Computational Fluid Dynamics Simulations}, note = {Accepted for publication in ETNA. October 2021.}, abbr = {ETNA}, preprint = {https://kups.ub.uni-koeln.de/29760/}, keywords = {accepted, reviewed, selected, recent}, bibtex_show = {true} }
SISC
Adaptive GDSW coarse spaces of reduced dimension for overlapping Schwarz methods

Heinlein, Alexander, Klawonn, Axel, Knepper, Jascha, Rheinbach, Oliver, and Widlund, Olof B.

Accepted for publication in SIAM Journal on Scientific Computing. October 2021

Abstract Bib Preprint

A new reduced dimension adaptive GDSW (Generalized Dryja-Smith-Widlund) overlapping Schwarz method for linear second-order elliptic problems in three dimensions is introduced. It is robust with respect to large contrasts of the coefficients of the partial differential equations. The condition number bound of the new method is shown to be independent of the coefficient contrast and only dependent on a user-prescribed tolerance. The interface of the nonoverlapping domain decomposition is partitioned into nonoverlapping patches. The new coarse space is obtained by selecting a few eigenvectors of certain local eigenproblems which are defined on these patches. These eigenmodes are energy-minimally extended to the interior of the nonoverlapping subdomains and added to the coarse space. By using a new interface decomposition the reduced dimension adaptive GDSW overlapping Schwarz method usually has a smaller coarse space than existing GDSW and adaptive GDSW domain decomposition methods. A robust condition number estimate is proven for the new reduced dimension adaptive GDSW method which is also valid for existing adaptive GDSW methods. Numerical results for the equations of isotropic linear elasticity in three dimensions confirming the theoretical findings are presented.
@techreport{Heinlein:2021:AGD, author = {Heinlein, Alexander and Klawonn, Axel and Knepper, Jascha and Rheinbach, Oliver and Widlund, Olof B.}, title = {Adaptive GDSW coarse spaces of reduced dimension for overlapping Schwarz methods}, note = {Accepted for publication in SIAM Journal on Scientific Computing. October 2021}, abbr = {SISC}, preprint = {https://kups.ub.uni-koeln.de/id/eprint/12113}, keywords = {accepted, reviewed, recent}, bibtex_show = {true} }