Very simple, carbuncle-free, boundary-layer-resolving, rotated-hybrid Riemann solvers H Nishikawa, K Kitamura Journal of Computational Physics 227 (4), 2560-2581, 2008 | 251 | 2008 |
Comparison of node-centered and cell-centered unstructured finite-volume discretizations: viscous fluxes B Diskin, JL Thomas, EJ Nielsen, H Nishikawa, JA White AIAA journal 48 (7), 1326-1338, 2010 | 209 | 2010 |
Beyond interface gradient: a general principle for constructing diffusion schemes H Nishikawa 40th fluid dynamics conference and exhibit, 5093, 2010 | 133 | 2010 |
A first-order system approach for diffusion equation. I: Second-order residual-distribution schemes H Nishikawa Journal of Computational Physics 227 (1), 315-352, 2007 | 118 | 2007 |
A first-order system approach for diffusion equation. II: Unification of advection and diffusion H Nishikawa Journal of Computational Physics 229 (11), 3989-4016, 2010 | 83 | 2010 |
Robust and accurate viscous discretization via upwind scheme–I: Basic principle H Nishikawa Computers & Fluids 49 (1), 62-86, 2011 | 61 | 2011 |
First-, second-, and third-order finite-volume schemes for diffusion H Nishikawa Journal of Computational Physics 256, 791-805, 2014 | 55 | 2014 |
New-generation hyperbolic Navier-Stokes schemes: O (1/h) speed-up and accurate viscous/heat fluxes H Nishikawa 20th AIAA Computational Fluid Dynamics Conference, 3043, 2011 | 54 | 2011 |
First, second, and third order finite-volume schemes for advection–diffusion H Nishikawa Journal of Computational Physics 273, 287-309, 2014 | 47 | 2014 |
Hyperbolic Navier-Stokes solver for three-dimensional flows Y Nakashima, N Watanabe, H Nishikawa 54th AIAA Aerospace Sciences Meeting, 1101, 2016 | 45 | 2016 |
Alternative formulations for first-, second-, and third-order hyperbolic Navier-Stokes schemes H Nishikawa 22nd AIAA Computational Fluid Dynamics Conference, 2451, 2015 | 45 | 2015 |
On high-order fluctuation-splitting schemes for Navier-Stokes equations H Nishikawa, P Roe Computational Fluid Dynamics 2004: Proceedings of the Third International …, 2006 | 40 | 2006 |
On carbuncles and other excrescences P Roe, H Nishikawa, F Ismail, L Scalabrin 17th AIAA Computational Fluid Dynamics Conference, 4872, 2005 | 37 | 2005 |
Two ways to extend diffusion schemes to navier-stokes schemes: Gradient formula or upwind flux H Nishikawa 20th AIAA Computational Fluid Dynamics Conference, 3044, 2011 | 36 | 2011 |
A critical study of agglomerated multigrid methods for diffusion on highly-stretched grids JL Thomas, B Diskin, H Nishikawa Computers & fluids 41 (1), 82-93, 2011 | 36 | 2011 |
Third-order inviscid and second-order hyperbolic navier-stokes schemes for three-dimensional inviscid and viscous flows Y Liu, H Nishikawa 46th AIAA Fluid Dynamics Conference, 3969, 2016 | 35 | 2016 |
Reconstructed discontinuous Galerkin methods for linear advection–diffusion equations based on first-order hyperbolic system J Lou, L Li, H Luo, H Nishikawa Journal of Computational Physics 369, 103-124, 2018 | 34 | 2018 |
Grid convergence for three dimensional benchmark turbulent flows B Diskin, WK Anderson, MJ Pandya, CL Rumsey, J Thomas, Y Liu, ... 2018 AIAA Aerospace Sciences Meeting, 1102, 2018 | 33 | 2018 |
Towards the ultimate understanding of MUSCL: Pitfalls in achieving third-order accuracy B van Leer, H Nishikawa Journal of Computational Physics 446, 110640, 2021 | 32 | 2021 |
Weighted least-squares cell-average gradient construction methods for The VULCAN-CFD second-order accurate unstructured grid cell-centered finite-volume solver JA White, H Nishikawa, RA Baurle AIAA Scitech 2019 Forum, 0127, 2019 | 32 | 2019 |