Articles

[18] R. Trunk, T. Henn, W. Dörfler, H. Nirschl and M.J. Krause. Inertial dilute particulate fluid flow simulations with an Euler–Euler lattice Boltzmann method. Journal of Computational Science, 2016. [ http DOI]
[17] A. Mink, G. Thäter, H. Nirschl and M.J. Krause. A 3D Lattice Boltzmann method for light simulation in participating media. Journal of Computational Science, 2016. [ http DOI]
[16] T. Henn, G. Thäter, and W. Dörfler, H. Nirschl and M.J. Krause. Parallel dilute particulate flow simulations in the human nasal cavity. Computers & Fluids, 124:197-207, 2016. [ http DOI]
[15] P. Nathen, D. Gaudlitz, M.J. Krause and J. Kratzke. An extension of the Lattice Boltzmann Method for simulating turbulent flows around rotating geometries of arbitrary shape. 21st AIAA Computational Fluid Dynamics Conference, San Diego, 2013. [ http DOI]
[14] M.J. Krause, G. Thäter and V. Heuveline. Adjoint-based Fluid Flow Control and Optimisation with Lattice Boltzmann Methods. Computers & Mathematics with Application, 65(6):945-960, 2013. [ http DOI]
[13] M.J. Krause and V. Heuveline. Parallel Fluid Flow Control and Optimisation with Lattice Boltzmann Methods and Automatic Differentiation. Computers and Fluids, 80(0):28-36, 2013. [ http DOI]
[12] T. Henn, M.J. Krause, S. Ritterbusch and V. Heuveline. Lattice Boltzmann Method Meets Aortic Coarctation Model. Medical Image Computing and Computer-Assisted Intervention — MICCAI 2012, Lecture Notes in Computer Science, Springer Berlin Heidelberg, 7746:34-43, 2012.
[11] J. Fietz, M.J. Krause, C. Schulz, P. Sanders and V. Heuveline. Optimized Hybrid Parallel Lattice Boltzmann Fluid Flow Simulations on Complex Geometries. Euro-Par 2012 Parallel Processing, Lecture Notes in Computer Science, Springer Berlin Heidelberg, 7484:818-829, 2012. [ http DOI]
[10] M.J. Krause, T. Gengenbach, R. Mayer, S. Zimny and V. Heuveline. How to Breathe Life into CT-Data. Computer Aided Medical Engineering, 4:29-33, 2011.
[9] M.J. Krause, T. Gengenbach, R. Mayer, S. Zimny and V. Heuveline. A Preprocessing Approach for Innovative Patient-specific Intranasal Flow Simulations. Preprint in EMCL Preprint Series, 2011-07, 2011. [ http ]
[8] M.J. Krause, T. Gengenbach and V. Heuveline. Hybrid Parallel Simulations of Fluid Flows in Complex Geometries: Application to the Human Lungs.Proceedings of Euro-Par 2010 – Parallel Processing Workshops: HeteroPar, HPPC, HiBB, CoreGrid, UCHPC, HPCF, PROPER, CCPI, VHPC, Ischia, Italy, August 31–September 3, 2010, Revised Selected Papers Springer-Verlag Berlin Heidelberg, 6586:209-216, 2011.[ http ]
[7] M.J. Krause. Fluid Flow Simulation and Optimisation with Lattice Boltzmann Methods on High Performance Computers: Application to the Human Respiratory System. Doktorarbeit / PhD thesis, Karlsruhe Institute of Technology (KIT), Karlsruhe, Germany, 2010. [ http ]
[6] V. Heuveline, M.J. Krause and J. Latt. Towards a hybrid parallelization of lattice Boltzmann methods. Computers & Mathematics with Applications, 58:1071-1080, 2009. [ bib  DOI  http ]
[5] V. Heuveline and M.J. Krause. OpenLB: Towards an Efficient Parallel Open Source Library for Lattice Boltzmann Fluid Flow Simulations. PARA’08 Workshop on State-of-the-Art in Scientific and Parallel Computing, May 13-16, 2008, 6126, 6127, 2011. [ http ]
[4] J. Latt, B. Chopard, O. Malaspinas, M. Deville, and A. Michler. Straight velocity boundaries in the lattice Boltzmann method. Phys. Rev. E, 77:056703, 2008. [ bib  DOI ]
[3] V. Heuveline and J. Latt. The OpenLB project: an open source and object oriented implementation of lattice Boltzmann methods. Int. J. Mod. Phys. C, 18:627-634, 2007. [ bib ]
[2] J. Latt. Hydrodynamic limit of lattice Boltzmann equations. PhD thesis, University of Geneva, Geneva, Switzerland, 2007. [ bib ]
[1] J. Latt and B. Chopard. Lattice Boltzmann method with regularized non-equilibrium distribution functions. Math. Comp. Sim., 72:165-168, 2006. [ bib DOI ]