Parallel computational fluid dynamics new frontiers and multi-disciplinary applications : proceedings of the Parallel CFD 2002 Conference, Kansai Science City, Japan (May 20-22, 2002) /
This volume is proceedings of the international conference of the Parallel Computational Fluid Dynamics 2002. In the volume, up-to-date information about numerical simulations of flows using parallel computers is given by leading researchers in this field. Special topics are "Grid Computing&quo...
| Άλλοι συγγραφείς: | Parallel CFD Conference, Matsuno, K. |
|---|---|
| Μορφή: | Ηλεκτρονική πηγή |
| Γλώσσα: | English |
| Στοιχεία έκδοσης: |
Amsterdam ; Boston :
North Holland/Elsevier,
2003.
|
| Έκδοση: | 1st ed. |
| Θέματα: | |
| Διαθέσιμο Online: |
http://www.sciencedirect.com/science/book/9780444506801 |
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Πίνακας περιεχομένων:
- Cover
- Table of Contents
- Preface
- Acknowledgements
- Part 1: Invited Papers
- Chapter 1. Lattice Boltzmann Methods: High Performance Computing and Engineering Applications
- Chapter 2. Multi-Disciplinary Simulations and Computational and Data Grids
- Chapter 3. A Different Approach to Large-Eddy Simulation with Advantages for Computing Turbulence-Chemical Kinetics Interactions
- Chapter 4. Simulation of Combustion Dynamics in Gas Turbine Engines
- Chapter 5. A Substepping Navier-Stokes Splitting Scheme for Spectral/hp Element Discretisations
- Part 2: Earth and Space Global Simulations and Earth Simulator
- Chapter 6. An MHD Model for Heliospheric Studies
- Chapter 7. Computational Performance of the Dynamical Part of a Next Generation Climate Model Using an Icosahedral Grid on the Earth Simulator
- Chapter 8. Optimization of a MHD Dynamo Simulation Code Using the GeoFEM for the Earth Simulator
- Chapter 9. Performance of Atmospheric General Circulation Model Using the Spectral Transform Method on the Earth Simulator
- Chapter 10. Improving Computational Efficiency of 4D-VAR System for Global Ocean Circulation Study
- Chapter 11. Coupling Strategy of Atmospheric-Oceanic General Circulation Model with Ultra High Resolution and its Performance on the Earth Simulator
- Chapter 12. Parallel Architecture and its Performance of Oceanic Global Circulation Model Based on MOM3 to Be Run on the Earth Simulator
- Chapter 13. Design and Performance Analysis of an Ocean General Circulation Model Optimized for the Earth Simulator
- Chapter 14. Development of a Nonhydrostatic General Circulation Model Using an Icosahedral Grid
- Chapter 15. Zonally Implicit Scheme for a Global Ocean Model
- Chapter 16. Successful Achievement in Developing the Earth Simulator
- Part 3: Parallel Environments
- Chapter 17. Simulation of Combustion Problems Using Multiprocessor Computer Systems
- Chapter 18. Autonomic System for Dynamic Load Balancing of Parallel CFD
- Chapter 19. High-Speed Mass Storage System of Numerical Simulator III and it's Basic I/O Performance Benchmark
- Chapter 20. Construction of a Large Scale PC-Cluster Machine and its Application to Combusting Flow Analysis in Chemical Furnace
- Chapter 21. Aerodynamic Computation of a Scramjet Engine on Vector-Parallel Supercomputers
- Chapter 22. A New Approach to Scientific Computing with JavaSpace
- Chapter 23. Numerical Simulator III
- Building a Terascale Distributed Parallel Computing Environment for Aerospace Science and Engineering
- Chapter 24. Blood Flow Simulation in a Grid Environment
- Chapter 25. Parallelization Methods for Three-Dimensional Fluid Code Using High Performance Fortran
- Chapter 26. The Development Strategy of Super-Computer Calculations in Russia.
- Chapter 27. Reaching Equilibrium for Non-Cooperative Dynamic Load Balancing Applications
- Chapter 28. The Parallel Flux Module of the National Combustion Code on Dynamic Load Balancing Environment
- Part 4: Parallel Algorithms
- Chapter 29. Numerical Simulation of Reaction-Diffusion and Adsorption Processes in Porous Media Using Lattice Boltzmann Methods with Concurrent Visualisation
- Chapter 30. A Parallel Multilevel Finite Element Solver for Axial Compres.