 09/17  present: Director Steinbuch Centre for Computing(SCC) at KIT and Professor for Computational Science and Mathematical Methods, Department of Mathematics at KIT

10/09  08/17: Professor at Dept. of Mathematics and Center for Computational Engineering Science, RWTH Aachen University

10/08  09/09 : Junior professor at Dept. of Mathematics, TU Kaiserslautern

10/04  09/08 : Research assistant at Dept. of Mathematics, TU Kaiserslautern

05/05 : PhD in Mathematics with A. Klar, TU Kaiserslautern

10/01  09/04 : Research assistant at Dept. of Mathematics, TU Darmstadt

04/97  02/04 : Studies in Mathematics and Physics, TU Darmstadt

02/04 : Diploma in Physics with J. Wambach

09/01 : Diploma in Mathematics with R. Farwig
CV
Publications
You can find citation data on my ResearcherID page.
Recent work
 T. Camminady, M. Frank, K. Kuepper, J. Kusch: Ray Effect Mitigation for the Discrete Ordinates Method through Quadrature Rotation, arXiv:1808.05846 [math.NA]
 J. Kusch, R.G. McClarren, M. Frank: Filtered Stochastic Galerkin Methods For Hyperbolic Equations, arXiv:1808.00819 [math.NA]
 M.P. Laiu, M. Frank, C.D. Hauck: A Positive Asymptotic Preserving Scheme for Linear Kinetic Transport Equations
 J. Kusch, G.W. Alldredge, M. Frank: Maximumprinciplesatisfying secondorder Intrusive Polynomial Moment scheme, arXiv:1712.06966 [math.NA]
 P. Richter, M. Frank, E. Abraham: Multiobjective optimization of solar tower heliostat fields
Journal publications
 J. Tervo, P. Kokkonen, M. Frank, M. Herty: On Approximative Linear Boltzmann Transport Equation for Charged Particle Transport, to appear in Math. Mod. Meth. Appl. Sci. (2018).
 T. Trimborn, M. Frank, S. Martin: Mean Field Limit of a Behavioral Financial Market Model, Physica A 505 (2018) 613631.
 P. Chidyagwai, M. Frank, F. Schneider, B. Seibold: A Comparative Study of Limiting Strategies in Discontinuous Galerkin Schemes for the M1 Model of Radiation Transport, J. Comput. Appl. Math. 342 (2018) 399418.
 M. Frank, C. Lax, S. Walcher, O. Wittich: Quasisteady state reduction for the MichaelisMenten reactiondiffusion system, J. Math. Chem. 56 (2018) 17591781.
 J. Tervo, P. Kokkonen, M. Frank, M. Herty: On existence of solutions for Boltzmann Continuous Slowing Down transport equation, J. Math. Anal. Appl. 460 (2018) 271301.
 M. Frank, W. Sun, Fractional Diffusion Limits of NonClassical Transport Equations, Kinet. Relat. Models 11 (2018) 15031526.
 T. Pichard, G.W. Alldredge, S. Brull, B. Dubroca, M. Frank: An approximation of the M 2 closure: application to radiotherapy dose simulation, J. Sci. Comput. 71 (2017) 71108.
 K. Kuepper, M. Frank, S. Jin: An Asymptotic Preserving 2D Staggered Grid Method for multiscale transport equations, SIAM J. Numer. Anal. 54 (2016) 440–461.
 P. Otte, M. Frank: Derivation and analysis of Lattice Boltzmann schemes for the linearized Euler equations, Comput. Math. Appl. Volume 72 (2016) 311–327.
 R.C. Barnard, M. Frank, K. Krycki: Sensitivity Analysis for Dose Deposition in Radiotherapy via a FokkerPlanck Model, Math. Med. Biol. (2016).
 M. Frank, C.D. Hauck, K. Kuepper: Convergence of Filtered Spherical Harmonic Equations for Radiation Transport, Commun. Math. Sci. 14 (2016) 1443–1465.
 T. Pichard, G. W. Alldredge, S. Brull, B. Dubroca, M. Frank: The M2 Model for Dose Simulation in Radiation Therapy, J. Comput. Theor. Transp. 45 (2016) 174183.
 T. Pichard, D. AregbaDriollet, S. Brull, B. Dubroca, M. Frank: Relaxation schemes for the M1 model with spacedependent flux: application to radiotherapy dose calculation, Commun. Comput. Phys. 19 (2015) 168191.
 J. Caron, J.L. Feugeas, B. Dubroca, G. Kantor, C. Dejean, T. Pichard, P. Nicolai, E. D'Humières, M. Frank, V. Tikhonchuk: Deterministic model for the transport of energetic particles. Application in the electron radiotherapy, Physica Medica 31 (2015) 912–921.
 M. Frank, K. Krycki, E.W. Larsen, R. Vasques: The NonClassical Boltzmann Equation, and DiffusionBased approximations to the Boltzmann Equation, SIAM J. Appl. Math. 75 (2015) 1329–1345.
 F. Schneider, G. Alldredge, M. Frank, A. Klar: Higher order mixed moment approximations for the FokkerPlanck equation in one space dimension, SIAM J. Appl. Math. 74 (2014) 1087–1114.
 B. Seibold, M. Frank: StaRMAP  A second order staggered grid method for spherical harmonics moment equations of radiative transfer, ACM Trans. Math. Softw. 41 (2014) 4.
 M. Frank, C.D. Hauck, E. Olbrant: Perturbed, EntropyBased Closure for Radiative Transfer, Kinet. Relat. Models 6 (2013) 557587.
 E. Olbrant, E.W. Larsen, M. Frank, B. Seibold: Asymptotic Derivation and Numerical Investigation of TimeDependent Simplified Pn Equations, J. Comput. Phys. 238 (2013) 315336.
 K. Krycki, C. Berthon, M. Frank, R. Turpault: Asymptotic preserving numerical schemes for a nonclassical radiation transport model for atmospheric clouds, Math. Meth. Appl. Sci. 36 (2013) 2101–2116.
 R. Barnard, M. Frank, M. Herty: Optimal radiotherapy treatment planning using minimum entropy models, Appl. Math. Comput. 219 (2012) 2668–2679.
 E. Olbrant, C.D. Hauck, M. Frank: A RealizabilityPreserving Discontinuous Galerkin Method for the M1 Model of Radiative Transfer, J. Comput. Phys. 231 (2012) 5612–5639.
 M. Frank, M. Herty, M. Hinze: Timedependent Closed Loop Control of the Radiative Transfer Equations with Applications in Radiotherapy, Z. Angew. Math. Mech. 92 (2012) 824.
 M. Frank, B. Seibold: Optimal Prediction for Radiative Transfer: A New Perspective on Moment Closure, Kinet. Relat. Models 4 (2011) 717733.
 M. Frank, J. Lang, M. Schäfer: Adaptive Finite Element Simulation of the TimeDependent Simplified PN Equations, J. Sci. Comput. 49 (2011) 332350.
 C. Berthon, M. Frank, C. Sarazin, R. Turpault: Numerical methods for balance laws with space dependent flux: application to radiotherapy dose calculation, Commun. Comput. Phys. 10 (2011) 11841210.
 M. Schäfer, M. Frank, C.D. Levermore: Diffusive Corrections to Pn approximations, Multiscale Model. Simul. 9 (2011) 128.
 M. Frank, A. Klar, R. Pinnau: Optimal Control of Glass Cooling Using Simplified Pn Theory, Transp. Theory Stat. Phys. 39 (2010) 282311.
 B. Dubroca, J.L. Feugeas, M. Frank: Angular moment model for the FokkerPlanck equation, Eur. Phys. J. D 60 (2010) 301–307.
 M. Frank, T. Goudon: On a generalized Boltzmann equation for nonclassical particle transport, Kinet. Relat. Models 3 (2010) 395407.
 E. Olbrant, M. Frank: Application of Generalized FokkerPlanck Theory To Electron And Photon Transport In Tissue, Comput. Math. Meth. Med. 11 (2010) 313339.
 R. Duclous, B. Dubroca, M. Frank: Deterministic Partial Differential Equation Model for Dose Calculation in Electron Radiotherapy, Phys. Med. Biol. 55 (2010) 38433857.
 M. Frank, A. Fügenschuh, M. Herty, L. Schewe: The Coolest Path Problem, Netw. Heterog. Media 5 (2010) 143162.
 M. Frank, M. Herty, A.N. Sandjo: Optimal Radiotherapy Treatment Planning Governed by Kinetic Equations, Math. Mod. Meth. Appl. Sci. 20 (2010) 661678.
 B. Seibold, M. Frank: Optimal prediction for moment models: crescendo diffusion and reordered equations, Continuum Mech. Thermodyn. 21 (2009) 511527.
 M. Frank, M. Herty, M. Schäfer: Optimal Treatment Planning in Radiotherapy Based On Boltzmann Transport Calculations, Math. Mod. Meth. Appl. Sci. 18 (2008) 573592.
 M. Frank, A. Klar, E.W. Larsen, S. Yasuda: Timedependent Simplified PN Approximation to the Equations of Radiative Transfer, J. Comput. Phys. 226 (2007) 22892305.
 M. Frank: Approximate models for radiative transfer, Bull. Inst. Math. Acad. Sinica (New Series) 2 (2007) 409432.
 M. Frank, H. Hensel, A. Klar: A fast and accurate moment method for the FokkerPlanck equation and applications to electron radiotherapy, SIAM J. Appl. Math. 67 (2007) 582603.
 M. Frank, R. Pinnau: Existence and Bounds for the Half Moment Entropy Approximation to Radiative Transfer, Appl. Math. Lett. 20 (2007) 189193.
 M. Frank, B. Dubroca, A. Klar: Partial Moment Entropy Approximation to Radiative Heat Transfer, J. Comput. Phys. 218 (2006) 118.
 M. Schäfer, M. Frank, R. Pinnau: A Hierarchy of Approximations to the Radiative Heat Transfer Equations: Modelling, Analysis and Simulation, Math. Mod. Meth. Appl. Sci. 15 (2005) 643665.
 R. Turpault, M. Frank, B. Dubroca, A. Klar: Multigroup half space moment appproximations to the radiative heat transfer equations, J. Comput. Phys. 198 (2004) 363371.
 M. Seaid, M. Frank, A. Klar, R. Pinnau, G. Thömmes: Efficient numerical methods for radiation in gas turbines, J. Comput. Appl. Math. 170 (2004) 217239.
 M. Frank, M. Seaid, J. Janicka, A. Klar, R. Pinnau: A comparison of approximate models for radiation in gas turbines, Progress in Computational Fluid Dynamics 4 (2004) 191197.
 M. Frank, M. Buballa, M. Oertel: Flavormixing effects on the QCD phase diagram at nonvanishing isospin chemical potential: one or two phase transitions?, Phys. Lett. B 562 (2003) 221226.
 B. Dubroca, M. Frank, A. Klar, G. Thömmes: A half space moment approximation to the radiative heat transfer equations, Z. Angew. Math. Mech. 83 (2003) 853858.
Mathematics Education
 M. Frank, C. Roeckerath: Augmenting Mathematics Courses by ProblemBased Learning, International Journal of Engineering Pedagogy (iJEP) 6 (2016), doi:10.3991/ijep.v6i1.5368
 M. Frank, M. Hattebuhr, C. Roeckerath: Augmenting Mathematics Courses by ProjectBased Learning, Proceedings of 2015 International Conference on Interactive Collaborative Learning (2015).
 M. Frank, C. Roeckerath: Wie kann man mit einer Handykamera Geschwindigkeiten messen?, Der Mathematikunterricht 61 (2015) 2731.
 M. Frank, C. Roeckerath: Habe ich das Zeug zum MINTStudium? Die CAMMP week als Orientierungshilfe für Schülerinnen und Schüler, in: Lehren und Lernen von Mathematik in der Studieneingangsphase, SpringerVerlag (2015) 181195.
 M. Frank, C. Roeckerath: Gemeinsam mit Profis reale Probleme lösen, Mathematik Lehren 174 (2012).
Refereed Proceedings

P. Richter, J. Tinnes, P. Schwarzbözl, A. Rong, M. Frank: Efficient RayTracing with Real Weather Data, to appear in AIP Conference Proceedings (2018).

P. Richter, G. Heiming, N. Lukas, M. Frank: SunFlower: A New Solar Tower Simulation Method For Use in Field Layout Optimization, to appear in AIP Conference Proceedings (2018).

C.A. DomínguezBravo, S.J. Bode, G. Heiming, P. Richter, E. Carrizosa, E. FernándezCara, M. Frank, P. Gauché: Fielddesign optimization with triangular heliostat pods, AIP Conference Proceedings 1734 (2016) 070006.

R. Barnard, M. Frank, M. Herty: Treatment Planning Optimization for Radiotherapy, Proc. Appl. Math. Mech. 13 (2013) 339–340.

R. Barnard, M. Frank, M. Herty: StateConstrained Optimization of PDEs via Infinite Penalization Methods, Proc. Appl. Math. Mech. 12 (2012) 691–692.
 K. Krycki, M. Frank: Numerical treatment of a nonclassical transport equation modelling radiative transfer in atmospheric clouds, Hyperbolic Problems: Theory, Numerics and Applications, Series in Contemporary Applied Mathematics 17&18 (2012) 502509.
 B. Dubroca, M. Frank: An Iterative Method for Transport Equations in Radiotherapy, Progress in Industrial Mathematics at ECMI 2008 (2010) 407412.
 M. Frank, M. Herty: Boundary control of radiative transfer equations for application in radiotherapy planning, Progress in Industrial Mathematics at ECMI 2008 (2010) 413418.
 D. Wright, M. Frank, A. Klar: The minimum entropy approximation to the radiative transfer equation, Proc. Symp. Appl. Math. 67 (2009) 987996.
 M. Frank, H. Hensel, A. Klar: Toward fast and accurate methods for dose calculation in radiotherapy, Proc. Appl. Math. Mech. 7 (2007) 200700407200700408.
 M. Schäfer, M. Frank, M. Herty: Optimal treatment planning in radiotherapy based on Boltzmann transport calculations, Proc. Appl. Math. Mech. 7 (2007) 20600272060028.
 M. Frank, H. Hensel, A. Klar: Toward fast and accurate deterministic methods for dose calculation in electron radiotherapy, IMECS 2007, 23612365.
 M. Schäfer, M. Frank, R. Pinnau: Partial Space Moment Approximation for Radiative Transfer, Proc. Appl. Math. Mech. 6 (2006) 761762.
 M. Frank: Partial Moment Entropy Approximation to Radiative Heat Transfer, Proc. Appl. Math. Mech. 5 (2005) 659660.
Contributions to Books
 R. Barnard, M. Frank, M. Herty: Optimal Treatment Planning in Radiotherapy Based on Boltzmann Transport Equations, in Trends in PDE Constrained Optimization, International Series of Numerical Mathematics, G. Leugering (et al.) (Eds.), Birkhäuser, 2014.
 M. Frank, K. Küpper, B. Seibold: StaRMAP  A second order staggered grid method for radiative transfer: Application in radiotherapy, in Advances In PDE Modeling and Computation, S. Sundar (ed.), Ane Books, 2014.
 M. Frank, A. Klar: Radiative Heat Transfer and Applications for Glass Production Processes, in Mathematical Models in the Manufacturing of Glass, Lecture Notes in Mathematics, A. Fasano (Ed.), Springer, 2011.
Theses
 M. Frank: Partial Moment Models for Radiative Transfer, Dissertation, Fachbereich Mathematik, TU Kaiserslautern, ShakerVerlag, Aachen, July 2005.
 M. Frank: Das QCDPhasendiagramm bei endlicher Isospindichte, Diplomarbeit, Fachbereich Physik, TU Darmstadt, July 2003.
 M. Frank: Stabilitätsanalyse einer gewöhnlichen Differentialgleichung mit zeitabhängiger Retardierung, Diplomarbeit, Fachbereich Mathematik, TU Darmstadt and Robert Bosch GmbH, Schwieberdingen, September 2001.
Projects
Our methodoriented research focuses on:

Approximate models for kinetic equations, especially moment models

Optimization with partial differential equations and uncertainty quantification
These techniques are applied to several application areas. Furthermore, in interdisciplinary projects the group acts as a bridge to transfer advanced mathematical techniques to realworld problems. Examples include:

Dose calculation and treatment plan optimization in radiotherapy

Simulation of oxygenation in tumor tissue

Photon transport in clouds

Steam simulation in solar thermal power plants

Crime modeling and traffic flow

Timedependent neutron transport

Uncertainty quantification in neutron transport cross sections
Detailed descriptions of selected projects are given below. Student projects can be found here.
Nondestructive elemental analysis of raw materials and contaminated sites  ZEBRA
Within the ZEBRA research project, an innovative measurement system is being developed for environmental and hazardous substance analysis. This measurement system is based on the prompt and delayed gamma neutron activation analysis (P&DGNAA). The project includes the construction and test operation of the measurement system and the development of new analytical methods for determining the mass fractions of all elements of the periodic system.
More information: ZEBRA
Simulating Heavy Ion Beams Numerically using Minimum Entropy Reconstructions  SHINE
The aim of this project is to develop a novel tool for the simulation of heavy ion beams as they are decelerated in thick targets. We want to characterize the spatial and energy distributions of all primary particles and secondary fragments in a target. This is relevant because ion beams are used in various fields: atomic physics (e.g. atomic collisions, ion capture), nuclear physics (e.g. the study of the structure of nuclei), electronics (e.g. deposition of elements), material science and chemistry (e.g. analysis of damage on the walls of a tokamak), biology (e.g. the study of the toxicology of cellular tissues by ion analysis). Additionally, several worldclass facilities are dedicated to these studies (e.g. FAIR in Germany, GANIL in France). Simulations of heavy ion beams are challenging for two main reasons. First, beams are difficult to capture with a gridbased method. Second, the simulations rely on measurements of the stopping power, and therefore must be regarded as uncertain. We therefore develop a new entropybased discretization scheme which allows both a subgrid resolution and at the same time a very detailed reconstruction that can capture beams. In addition, we will use a similar method to characterize the uncertainties in the particle distribution due to uncertain stopping powers. The method is computationally challenging but highly parallelizable, and therefore ideally suited for modern computer architectures.
More information: SHINE
Moment Models for Radiative Transfer
Developing simplified methods for the simulation of radiative transfer requires taking into account the physical situation that will be analyzed. There are two important limits: optically thick and optically thin media. The different regimes can be characterized by the mean free paths for scattering and for absorption. One problem in this characterization is, that many materials are optically thick in a specific frequency range and optically thin in other ranges. Additionally, there is a transition regime between the two. For instance, during the reentry of a space craft into the atmosphere the regime goes from optically thin (space) through a transition (higher atmosphere) into optically thick (lower atmosphere).
Methods that work well in optically thin media are computationally too expensive in these regimes. Methods that work well in optically thick media, on the other hand, give poor results for low order approximations and have high computational costs if one increases the order. Therefore, in these regimes new methods have to be developed.
These new approximations have to recover traditional reduced models for small mean free paths. Further, in the transition regime, they have to be more accurate than the simplified models and should be solvable more efficiently than the full kinetic approaches.
The field of use for transition regime models can be found in standalone solvers for problems that lie completely within the optically thick and transition regime. For problems where the order of the mean free path also covers the optically thin regime, the new approaches could be used in hybrid methods.
Deterministic Methods for Dose Calculation in Radiotherapy
High energy ionizing radiation is a prominent modality for the treatment of many cancers. The approaches to dose calculation can be categorized into semiempirical models (e.g. FermiEyges, convolutionsuperposition) and probabilistic methods (e.g. Monte Carlo). A third way to dose calculation has only recently attracted attention in the medical physics community. This approach is based on the deterministic kinetic equations of radiative transfer. In this project, we investigate macroscopic partial differential equation models for particle transport in tissue. The models reduce computational cost, and at the same time preserve key properties of the mesoscopic equation.
The figures show the isodose curves in the case where the vertebral column is irradiatied by 12 MeV electrons. The first figure shows the results obtained with the PenEasy2009 benchmark code, the second figure the results obtained with the reduced model.
Optimal Treatment Planning in Radiotherapy based on Boltzmann Transport Equations
We study optimal control problems modelling clinical external beam radiotherapy. We use the Boltzmann transport equations to model the distribution of radiation through the body. Mathematically, this consists of an integropartial differential equation which depends on variables in space, energy, and angular direction. Several avenues of investigation are followed. Objective functions which accurately model the response of tumor cells to dose distributions while also describing the clinical requirements for an effective treatment plan will be developed. With these new models, the existence and regularity of the corresponding optimal treatment plans will be studied. Additionally, we pursue the use of moment approximations to the highdimensional phase space to create efficient numerical schemes for the solution of the optimization problem; the relationship between these approximations and the optimization methods employed will be investigated. Closedloop control schemes for use in timedependent 4D radiotherapy will also be developed. Optimal treatment plans will be simulated on real CTpatient data and compared with standard MonteCarlo methods for the solution of control problems.
The picture shows an optimal boundary control for an Lshaped tumor, which encloses a risk region. The contour lines show the isodose curves, whereas the arrows visualize the boundary control. The density of the medium is depicted as the gray scale of the background. the black ring is a void region.
Dose Visualization in 3D
Dose distributions in the body are genuinely threedimensional. Most of the time, they are visualized by twodimensional slices. In order to compare standard dose calculation results with newly developed deterministic methods, and as a didactical means to explain these new methods, threedimensional visualizations have been developed in collaboration with the VR group at RWTH Aachen University. Results can be viewed both on desktop computers and on the VR system at AICES. Future developments include the visualization of an optimization process using adjoint information. Data courtesy of the National Library of Medicine Visible Human Project.
The following video shows streamlines of the electron flow by which dose is deposited in the chest.
This video shows the same situation with pseudoparticles (requires anaglyph glasses). The size and color is the particle energy.
Nonclassical Transport in Clouds
In classical particle transport, the probability that a particle interacts with the background medium is proportional to the path length traveled by that particle, and the proportionality constant depends on the density of the medium and on the particle’s energy. This typically leads to an exponential attenuation law, i.e. the particle flux decreases as an exponential function of the path length (BeerLambert law). In cloud physics, however, recent experimental studies point toward a nonexponential attenuation law. It has been suggested that spatial correlations between the water droplets (scattering centers) within a cloud could be responsible for this behavior. This hypothesis has sparked a vivid discussion in the recent literature.
In this project, we investigate a nonclassical Boltzmann equation proposed by Larsen. We have rigorously established the convergence of the solution in the diffusion limit. We will develop numerical schemes for the efficient solution of the extended Boltzmann model.
Direct Steam Simulation in Solar Thermal Power Plants
Concentrated solar power systems are systems that use mirrors to concentrate sunlight to heat a fluid. The heated fluid is converted into steam which drives a turbine to generate electrical power.
There exist different types of concentrators. For example, Fresnel reflectors (see figure) are made of many thin, flat mirror strips that concentrate sunlight onto tubes through which a working fluid is pumped. The idea of direct steam generation is to use water as the working fluid.
In this project we consider the flow of water inside an absorber tube. This twophase flow is modeled as a homogeneous flow. Specifically, the flow is governed by the 1D Euler equations. The influence of solar energy is described by a heat equation which is coupled with the flow. Due to a specific closure relation for the twophase flow, the system is in a nonconservative form. We will develop a model and numerical schemes to simulate the flow through a realistic network of tubes.
Neutron Imaging System for Radioactive Waste Analysis
Similar to xrays, neutrons can be used for imaging. The advantage of fast neutrons with respect to xrays is their deeper penetration depth into dense materials. This project deals with the development of a compact neutron radiography system, which can be used in addition to existing imaging techniques. The main aplication is the characterization of radioactive waste, but the technology can be used e.g. for electronics recycling, quality control in manufacturing, engine design, among others. In a collaborative project, we develop image reconstruction algorithms based on the radiative transfer equation. The main focus is the correction of diverging beams.
Extinction Photometry for the Characterization of a MultiComponent Aerosol
This project aims at improving measurement techniques for the characterization of the composition of an aerosol. The main goal is to implement, adapt and improve the method of Mie inversion so that physically correct particle size distributions can be obtained from measured spectra automatically without an operator.
Analysis and Numerics of KineticContinuum Coupling
In numerical methods for engineering applications, there are three basic methods which can be applied: either we work with continuum equations (macroscopic level), or with individual particles (microscopic), or as a third approach we use a probability density for the distribution of the particles for which we solve solve a PDE (mesoscopic). Each of the three has its advantages and disadvantages, therefore our approach is to couple them such that in each part of the simulation domain, we apply the bestsuited methodology. This requires special analysis of the coupling method itself. Typically this is based on asymptotic approaches which under given restrictions / assumptions tend to the desired set of equations on the other side of the coupling interface. These assumptions have to be matched with the properties of the numerical schemes. Special focus will be put on the coupling of the Lattice Boltzmann method with linearized Euler equations for aeroacoustic simulation.
Lectures and Seminars
Titel  Typ  Semester  Ort 

Uncertainty Quantification  Vorlesung (V)  SS 2018  
Oberseminar Computational Science and Mathematical Methods  Seminar (S)  SS 2018 
Titel  Typ  Semester  Ort 

Seminar (Computational Science and Mathematical Methods)  Seminar (S)  WS 18/19  
Introduction to Kinetic Theory  Vorlesung (V)  WS 18/19 
Older Lectures and Seminars
 Numerical Analysis II, RWTH Aachen, summer term 2017

Mathematics IV (CES), RWTH Aachen, summer term 2017

Introduction to Transport Theory, RWTH Aachen, summer term 2017
 Numerical Analysis I, RWTH Aachen, winter term 2016/17
 Mathematics III (CES), RWTH Aachen, winter term 2016/17

Uncertainty Quantification, RWTH Aachen, winter term 2016/17

Partial Differential Equations (CES), RWTH Aachen, winter term 2015/16

Seminar AsymptoticPreserving Numerical Schemes, RWTH Aachen, winter term 2015/16

Mathematics IV (CES), RWTH Aachen, summer term 2015

Computational and Statistical Inverse Problems, RWTH Aachen, summer term 2015

Mathematics III (CES), RWTH Aachen, winter term 2014/15

Computational Nuclear Engineering, RWTH Aachen, winter term 2014/15

Seminar Hydrodynamic Limits of the Boltzmann Equation, RWTH Aachen, winter term 2014/15

Mathematics II (CES), RWTH Aachen, summer term 2014

Uncertainty Quantification, RWTH Aachen, summer term 2014

Partial Differential Equations (CES), RWTH Aachen, winter term 2013/14

Computational Nuclear Engineering, RWTH Aachen, winter term 2013/14

Mathematics IV (CES), RWTH Aachen, summer term 2013

Introduction to Transport Theory, RWTH Aachen, summer term 2013

Mathematics III (CES), RWTH Aachen, winter term 2012/13

Uncertainty Quantification, RWTH Aachen, winter term 2012/13

Computational Nuclear Engineering, RWTH Aachen, winter term 2012/13

Mathematics III (CES), RWTH Aachen, winter term 2011/12

Computational Nuclear Engineering, RWTH Aachen, winter term 2011/12

Seminar on Nonsmooth Analysis & Applied Optimization, RWTH Aachen, winter term 2011/12

Mathematics IV (CES), RWTH Aachen, summer term 2011

Introduction to Transport Theory, RWTH Aachen, summer term 2011

Seminar on Ordinary Differential Equations, RWTH Aachen, summer term 2011

Mathematics III (CES), RWTH Aachen, winter term 2010/11

Partial Differential Equations (CES), RWTH Aachen, winter term 2010/11

Mathematics II (CES), RWTH Aachen, summer term 2010

Mathematics IV (CES), RWTH Aachen, summer term 2010

Introduction to Transport Theory, RWTH Aachen, summer term 2010

Mathematics I (CES), RWTH Aachen, winter term 2009/10

Mathematics III (CES), RWTH Aachen, winter term 2009/10

Introduction to Numerical Mathematics, TU Kaiserslautern, winter term 2008/09

Mathematics III for Engineers, TU Kaiserslautern, winter term 2008/09

Mathematics II for Engineers, TU Kaiserslautern, winter term 2007/08

Mathematics I for Engineers, TU Kaiserslautern, summer term 2007

Proseminar Fractal Geometry, TU Kaiserslautern, winter term 2005/06

Seminar Partial Differential Equations, TU Kaiserslautern, winter term 2005/06
Modeling Projects

CAMMP Modeling Week in Aachen, RWTH Aachen, September 2017

CAMMP Modeling Week in Voeren, RWTH Aachen, June 2017

CAMMP Modeling Week in Aachen, RWTH Aachen, September 2016

CAMMP Modeling Week in Voeren, RWTH Aachen, June 2016

CAMMP Modeling Week in Aachen, RWTH Aachen, September 2015

CAMMP Modeling Week in Voeren, RWTH Aachen, June 2015

CAMMP Modeling Week in Aachen, RWTH Aachen, September 2014

CAMMP Modeling Week in Voeren, RWTH Aachen, June 2014

CAMMP Modeling Week in Aachen, RWTH Aachen, November 2014

CAMMP Modeling Week in Voeren, RWTH Aachen, July 2013

CAMMP Modeling Week in Voeren, RWTH Aachen, July 2012

CAMMP Modeling Week in Nideggen, RWTH Aachen, May 2011

ECMI Modeling Week in Rouen, France, TU Kaiserslautern, August 2007

Modeling Week in Lambrecht, TU Kaiserslautern, July 2005

Modeling Week in Termeno, Italy, TU Kaiserslautern, March 2005

Proseminar Mathematical Modeling, TU Kaiserslautern, winter term 2004/05

Proseminar I  Mathematical Modeling, TU Darmstadt, winter term 2003/04

Modeling Week in Fuldatal, TU Darmstadt, September/October 2003

Seminar on Mathematical Modeling, TU Darmstadt, winter term 2002/03

Modeling Week in Hoechst, TU Darmstadt, September/October 2002
CAMMP (Computational and Mathematical Modeling Program)
Modeling projects are ideal ways to teach problem solving capabilities. Students are faced with a realworld problem that is not formulated in the language of Mathematics. In order to translate the problem, it is neccessary to read literature from other disciplines. Each group of students learns Mathematics by doing it. The project aims can be adapted to the group’s capabilities so that weaker students gain motivation by solving easier problems, while stronger students can be challenged by more complicated additional questions. Problemsolving skills can be assessed by industrial case studies in the final year. The students are confronted with a real problem, have to do research, have to work in a team and in the end have to present their results in a comprehensible way. To facilitate problembased learning, I have cofounded the education lab CAMMP (Computational and Mathematical Modeling Program) at RWTH Aachen. Our activities in Karlsruhe can be found here.