Year Author
  1. Radman, S.; Fiorina, C. and Pautz, A. Development of a novel two-phase flow solver for nuclear reactor analysis: algorithms, verification and implementation in OpenFOAM. In Nuclear Engineering and Design, 379: 111178, 2021. BibTeX
  2. Hassanaly, M.; Koo, H.; Lietz, C. F.; Chong, S. T. and Raman, V. A minimally-dissipative low-Mach number solver for complex reacting flows in OpenFOAM. In Computers and Fluids, 162: 11–25, 2018. BibTeX
  3. Noriegašpace0mm, H.; Guibault, F.; Reggio, M. and Magnan, R. A case-study in open-source CFD code verification, Part I: Convergence rate loss diagnosis. In Mathematics and Computers in Simulation, 147: 152–171, 2018. BibTeX
  4. Noriega, H.; Guibault, F.; Reggio, M. and Magnan, R. A case-study in open-source CFD code verification. Part II: Boundary condition non-orthogonal correction. In Mathematics and Computers in Simulation, 147: 172–193, 2018. BibTeX
  5. Costa, R.; Clain, S.; Machado, G. J and Loubère, R. A very high-order accurate staggered finite volume scheme for the stationary incompressible Navier–Stokes and Euler equations on unstructured meshes. In Journal of Scientific Computing, 71 (3): 1375–1411, 2017. BibTeX
  6. Costa, R.; Clain, S. and Machado, G. J. A sixth-order finite volume scheme for the steady-state incompressible Stokes equations on staggered unstructured meshes. In Journal of Computational Physics, 349: 501-527, 2017. BibTeX
  7. Choudhary, A.; Roy, C. J.; Luke, E. A. and Veluri, S. P. Code verification of boundary conditions for compressible and incompressible computational fluid dynamics codes. In Computers & Fluids, 126: 153–169, 2016. BibTeX
  8. Habla, F.; Fernandes, C.; Maier, M.; Densky, L.; Ferrás, L.L.; Rajkumar, A.; Carneiro, O.S.; Hinrichsen, O. and Nóbrega, J. M. Development and validation of a model for the temperature distribution in the extrusion calibration stage. In Applied Thermal Engineering, 100: 538-552, 2016. BibTeX
  9. Blais, B. and Bertrand, F. On the use of the method of manufactured solutions for the verification of CFD codes for the volume-averaged Navier-Stokes equations. In Computers and Fluids, 114: 121–129, 2015. BibTeX
  10. Fisch, R.; Franke, J.; Wüchner, R. and Bletzinger, K. Code verification of a partitioned FSI environment for wind engineering applications using the method of manufactured solutions. In 11th World Congress on Computational Mechanics, WCCM 2014, 5th European Conference on Computational Mechanics, ECCM 2014 and 6th European Conference on Computational Fluid Dynamics, ECFD 2014 (Wccm Xi): 2186–2197, 2014. BibTeX
  11. Fisch, R.; Franke, J.; W”uchner, R. and Bletzinger, K-U. Code verification examples of a fully geometrical nonlinear membrane element using the method of manufactured solutions. In Textile Composites and Inflatable Structures VI – Proceedings of the 6th International Conference on Textile Composites and Inflatable Structures, Structures Membranes, pages 102–113, 2013. BibTeX
  12. Oberkampf, W. L and Roy, C. J Verification and validation in scientific computing. Cambridge University Press, 2010. BibTeX
  13. Roy, C. J.; Nelson, C. C.; Smith, T. M. and Ober, C. C. Verification of Euler/Navier-Stokes codes using the method of manufactured solutions. In International Journal for Numerical Methods in Fluids, 44 (6): 599–620, 2004. BibTeX
  14. Roache, P. J. Code verification by the method of manufactured solutions. In Journal of Fluids Engineering, Transactions of the ASME, 124 (1): 4–10, 2002. BibTeX
  15. Weller, H. G.; Ramoa, B.; Jasak, H. and Fureby, C. A tensorial approach to computational continuum mechanics using object orientated techniques. In Computers in Physics, 12: 620-631, 1998. BibTeX
  16. Roache, P. J Verification and validation in computational science and engineering. Hermosa Albuquerque, NM, 1998. BibTeX