| LBM based flow simulation using GPU computing processor F Kuznik, C Obrecht, G Rusaouen, JJ Roux Computers & Mathematics with Applications 59 (7), 2380-2392, 2010 | 268 | 2010 |
| A new approach to the lattice Boltzmann method for graphics processing units C Obrecht, F Kuznik, B Tourancheau, JJ Roux Computers & Mathematics with Applications 61 (12), 3628-3638, 2011 | 205 | 2011 |
| Multi-GPU implementation of the lattice Boltzmann method C Obrecht, F Kuznik, B Tourancheau, JJ Roux Computers & Mathematics with Applications 65 (2), 252-261, 2013 | 167 | 2013 |
| Design and characterisation of a high powered energy dense zeolite thermal energy storage system for buildings K Johannes, F Kuznik, JL Hubert, F Durier, C Obrecht Applied Energy 159, 80-86, 2015 | 127 | 2015 |
| Scalable Lattice Boltzmann Solvers for CUDA GPU Clusters C Obrecht, F Kuznik, B Tourancheau, JJ Roux Parallel Computing 39 (6-7), 259-270, 2013 | 81 | 2013 |
| A review on recent developments in physisorption thermal energy storage for building applications F Kuznik, K Johannes, C Obrecht, D David Renewable and Sustainable Energy Reviews 94, 576-586, 2018 | 56 | 2018 |
| Multi-GPU Implementation of a Hybrid Thermal Lattice Boltzmann Solver using the TheLMA Framework C Obrecht, F Kuznik, B Tourancheau, JJ Roux Computers & Fluids 80, 269-275, 2013 | 40 | 2013 |
| Towards aeraulic simulations at urban scale using the lattice Boltzmann method C Obrecht, F Kuznik, L Merlier, JJ Roux, B Tourancheau Environmental Fluid Mechanics 15, 753-770, 2015 | 39 | 2015 |
| The TheLMA project: a thermal lattice Boltzmann solver for the GPU C Obrecht, F Kuznik, B Tourancheau, JJ Roux Computers & Fluids 54, 118-126, 2012 | 35 | 2012 |
| Chemisorption heat storage in buildings: State-of-the-art and outlook F Kuznik, K Johannes, C Obrecht Energy and Buildings 106, 183-191, 2015 | 31 | 2015 |
| The TheLMA project: Multi-GPU implementation of the lattice Boltzmann method C Obrecht, F Kuznik, B Tourancheau, JJ Roux International Journal of High Performance Computing Applications 25 (3), 295-303, 2011 | 26 | 2011 |
| Numerical modelling and investigations on a full-scale zeolite 13X open heat storage for buildings F Kuznik, D Gondre, K Johannes, C Obrecht, D David Renewable Energy 132, 761-772, 2019 | 25 | 2019 |
| Global memory access modelling for efficient implementation of the lattice Boltzmann method on graphics processing units C Obrecht, F Kuznik, B Tourancheau, JJ Roux Lecture Notes in Computer Science 6449, 151-161, 2011 | 20 | 2011 |
| Efficient GPU implementation of the linearly interpolated bounce-back boundary condition C Obrecht, F Kuznik, B Tourancheau, JJ Roux Computers & Mathematics with Applications 65 (6), 936-944, 2013 | 16 | 2013 |
| High-performance implementations and large-scale validation of the link-wise artificial compressibility method C Obrecht, P Asinari, F Kuznik, JJ Roux Journal of Computational Physics 275, 143-153, 2014 | 14 | 2014 |
| Thermal link-wise artificial compressibility method: GPU implementation and validation of a double-population model C Obrecht, P Asinari, F Kuznik, JJ Roux Computers & Mathematics with Applications 72 (2), 375-385, 2016 | 13 | 2016 |
| Sensitivity analysis of a zeolite energy storage model: Impact of parameters on heat storage density and discharge power density F Kuznik, D Gondre, K Johannes, C Obrecht, D David Renewable Energy 149, 468-478, 2020 | 12 | 2020 |
| Improving 3D Lattice Boltzmann Method stencil with asynchronous transfers on many-core processors MQ Ho, C Obrecht, B Tourancheau, BD de Dinechin, J Hascoet 2017 IEEE 36th International Performance Computing and Communications …, 2017 | 11 | 2017 |
| Eukleides C Obrecht | 11 | 2000 |
| Lattice Boltzmann model approximated with finite difference expressions F Dubois, P Lallemand, C Obrecht, MM Tekitek Computers & Fluids 155, 3-8, 2017 | 10 | 2017 |
J.-J. RouxINSA LyonVerified email at insa-lyon.fr
