R. L. Taylor, P. Nithiarasu

The Finite Element Method for Fluid Dynamics (eBook, ePUB)

• Format: ePub

Produktbeschreibung

The Finite Element Method for Fluid Dynamics provides a comprehensive introduction to the application of the finite element method in fluid dynamics. The book begins with a useful summary of all relevant partial differential equations, progressing to the discussion of convection stabilization procedures, steady and transient state equations, and numerical solution of fluid dynamic equations. In this expanded eighth edition, the book starts by explaining the character-based split (CBS) scheme, followed by an exploration of various other methods, including SUPG/PSPG, space-time, and VMS methods. Emphasising the fundamental knowledge, mathematical, and analytical tools necessary for successful implementation of computational fluid dynamics (CFD), The Finite Element Method for Fluid Dynamics stands as the authoritative introduction of choice for graduate level students, researchers, and professional engineers. - A proven keystone reference in the library for engineers seeking to grasp and implement the finite element method in fluid dynamics - Founded by a prominent pioneer in the field, this eighth edition has been updated by distinguished academics who worked closely with Olgierd C. Zienkiewicz - Includes new chapters on data-driven computational fluid dynamics and independent adaptive mesh and buoyancy driven flow chapters.

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Produktdetails

• Verlag: Elsevier Science & Techn.
• Seitenzahl: 584
• Erscheinungstermin: 20. November 2024
• Englisch
• ISBN-13: 9780323958875
• Artikelnr.: 72315544

Autorenporträt

R.L Taylor is a Professor of the Graduate School at the Department of Civil and Environmental Engineering, University of California, Berkeley, USA. Awarded the Daniel C. Drucker Medal by the American Society of Mechanical Engineering in 2005, the Gauss-Newton Award and Congress Medal by the International Association for Computational Mechanics in 2002, and the Von Neumann Medal by the US Association for Computational Mechanics in 1999.P. Nithiarasu is Professor at Zienkiewicz Institute for Modelling, Data and AI and Associate Dean for Research, Innovation and Impact, Faculty of Science and Engineering, Swansea University. Previously he has served as the Head of Zienkiewicz Centre for Computational Engineering, Deputy Head of College of Engineering and Dean of Academic Leadership. He was awarded the Zienkiewicz silver medal from the ICE London in 2002, the ECCOMAS Young Investigator award in 2004, and the prestigious EPSRC Advanced Fellowship in 2006.

Inhaltsangabe

1. The equations of fluid dynamics 2. The finite element approximation 3. Convection dominated problems
finite element approximations to the convection
diffusion
reaction equation 4. Fractional step methods: the characteristic
based split (CBS) algorithm for compressible and incompressible flows 5. Incompressible Newtonian laminar flows 6. Incompressible non
Newtonian flows 7. Free surface flows 8. Buoyancy driven flows 9. Compressible high
speed gas flow 10. Adaptive mesh refinement 11. Turbulent flows 12. Flow and heat transport in porous media 13. Shallow
water problems 14. Long and medium waves 15. Short waves 16. Fluid
structure interaction 17. Biofluid dynamics
blood flow 18. Data
driven methods 19. Computer implementation of the CBS algorithm Appendix A: Self
adjoint differential equations Appendix B: Non
conservative form of Navier
Stokes equations Appendix C: Computing drag force and stream function Appendix D: Convection
diffusion equations: vector
valued variables Appendix E: Integration formulae Appendix F: Edge
based finite element formulation Appendix G: Boundary layer
inviscid flow coupling Appendix H: Multigrid method Appendix I: Mass
weighted averaged turbulence transport equations Appendix J: Introduction to neural networks