| Computing the electrical activity in the heart J Sundnes, GT Lines, X Cai, BF Nielsen, KA Mardal, A Tveito Springer Science & Business Media, 2007 | 615 | 2007 |
| Introduction to partial differential equations: a computational approach A Tveito, R Winther Springer New York, 1998 | 376 | 1998 |
| Penalty and front-fixing methods for the numerical solution of American option problems BF Nielsen, O Skavhaug, A Tveito Journal of Computational Finance 5 (4), 69-98, 2002 | 230 | 2002 |
| An operator splitting method for solving the bidomain equations coupled to a volume conductor model for the torso J Sundnes, GT Lines, A Tveito Mathematical biosciences 194 (2), 233-248, 2005 | 206 | 2005 |
| On the computational complexity of the bidomain and the monodomain models of electrophysiology J Sundnes, BF Nielsen, KA Mardal, X Cai, GT Lines, A Tveito Annals of biomedical engineering 34 (7), 1088-1097, 2006 | 162 | 2006 |
| Mathematical models and numerical methods for the forward problem in cardiac electrophysiology GT Lines, ML Buist, P Grottum, AJ Pullan, J Sundnes, A Tveito Computing and Visualization in Science 5 (4), 215-239, 2003 | 151 | 2003 |
| A cell-based framework for numerical modeling of electrical conduction in cardiac tissue A Tveito, KH Jæger, M Kuchta, KA Mardal, ME Rognes Frontiers in Physics 5, 48, 2017 | 126 | 2017 |
| Penalty methods for the numerical solution of American multi-asset option problems BF Nielsen, O Skavhaug, A Tveito Journal of Computational and Applied Mathematics 222 (1), 3-16, 2008 | 102 | 2008 |
| Efficient solution of ordinary differential equations modeling electrical activity in cardiac cells J Sundnes, GT Lines, A Tveito Mathematical biosciences 172 (2), 55-72, 2001 | 102 | 2001 |
| Metabolically driven maturation of human-induced-pluripotent-stem-cell-derived cardiac microtissues on microfluidic chips N Huebsch, B Charrez, G Neiman, B Siemons, SC Boggess, S Wall, ... Nature biomedical engineering 6 (4), 372-388, 2022 | 98 | 2022 |
| Multigrid block preconditioning for a coupled system of partial differential equations modeling the electrical activity in the heart J Sundnes, GT Lines, KA Mardal, A Tveito Computer Methods in Biomechanics & Biomedical Engineering 5 (6), 397-409, 2002 | 97 | 2002 |
| Advanced topics in computational partial differential equations: numerical methods and diffpack programming HP Langtangen, A Tveito Springer Science & Business Media, 2012 | 94 | 2012 |
| Modeling the electrical activity of the heart: a bidomain model of the ventricles embedded in a torso GT Lines, P Grottum, A Tveito Computing and Visualization in Science 5 (4), 195-213, 2003 | 90 | 2003 |
| An evaluation of the accuracy of classical models for computing the membrane potential and extracellular potential for neurons A Tveito, KH Jæger, GT Lines, Ł Paszkowski, J Sundnes, AG Edwards, ... Frontiers in computational neuroscience 11, 27, 2017 | 81 | 2017 |
| A second-order algorithm for solving dynamic cell membrane equations J Sundnes, R Artebrant, O Skavhaug, A Tveito IEEE Transactions on Biomedical Engineering 56 (10), 2546-2548, 2009 | 75 | 2009 |
| Optimal monodomain approximations of the bidomain equations BF Nielsen, TS Ruud, GT Lines, A Tveito Applied Mathematics and Computation 184 (2), 276-290, 2007 | 74 | 2007 |
| Numerical solution of the bidomain equations S Linge, J Sundnes, M Hanslien, GT Lines, A Tveito Philosophical Transactions of the Royal Society A: Mathematical, Physical …, 2009 | 73 | 2009 |
| On the rate of convergence to equilibrium for a system of conservation laws with a relaxation term A Tveito, R Winther SIAM Journal on Mathematical Analysis 28 (1), 136-161, 1997 | 73 | 1997 |
| Numerical solution of partial differential equations on parallel computers A Tveito, AM Bruaset Springer, 2006 | 70 | 2006 |
| Properties of cardiac conduction in a cell-based computational model KH Jæger, AG Edwards, A McCulloch, A Tveito PLoS computational biology 15 (5), e1007042, 2019 | 69 | 2019 |
Glenn Terje LinesSimula Research LaboratoryVerified email at simula.no
