Mesh Adaptation for Computational Fluid Dynamics, Volume 2
Unsteady and Goal-oriented Adaptation
1. Auflage November 2022
240 Seiten, Hardcover
Wiley & Sons Ltd
Preis: 152,00 €
Preis inkl. MwSt, zzgl. Versand
Simulation technology, and computational fluid dynamics (CFD) in particular, is essential in the search for solutions to the modern challenges faced by humanity. Revolutions in CFD over the last decade include the use of unstructured meshes, permitting the modeling of any 3D geometry. New frontiers point to mesh adaptation, allowing not only seamless meshing (for the engineer) but also simulation certification for safer products and risk prediction.
Mesh Adaptation for Computational Dynamics 2 is the second of two volumes and introduces topics including optimal control formulation, minimizing a goal function, and extending the steady algorithm to unsteady physics. Also covered are multi-rate strategies, steady inviscid flows in aeronautics and an extension to viscous flows.
This book will be useful to anybody interested in mesh adaptation pertaining to CFD, especially researchers, teachers and students.
2. Multi-scale Adaptation for Unsteady Flows.
3. Multi-rate Time Advancing.
4. Goal-Oriented Adaptation for Inviscid Steady Flows.
5. Goal-Oriented Adaptation for Viscous Steady Flows.
6. Norm-Oriented Formulations.
7. Goal-Oriented Adaptation for Unsteady Flows.
8. Third-Order Unsteady Adaptation.
Frederic Alauzet is a senior researcher at Inria Saclay and adjunct professor at Mississippi State University. His research focuses on anisotropic mesh adaptation, advanced solvers, mesh generation and moving mesh methods.
Adrien Loseille is a research scientist at Inria Saclay, working in Luminary Cloud. His main domains of interest are unstructured mesh generation and adaptation for computational fluid dynamics.
Bruno Koobus is professor at the University of Montpellier. His main research interests cover computational fluid dynamics, in particular the development of numerical methods on fixed and moving meshes, turbulence modeling and parallel algorithms.