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E-raamat: Frontiers of Computational Fluid Dynamics 2002 2002 [World Scientific e-raamat]

Edited by (Cornell Univ, Usa), Edited by (Univ Of California, Davis, Usa)
  • Formaat: 524 pages
  • Ilmumisaeg: 05-Dec-2001
  • Kirjastus: World Scientific Publishing Co Pte Ltd
  • ISBN-13: 9789812810793
Teised raamatud teemal:
  • World Scientific e-raamat
  • Hind: 188,50 €*
  • * hind, mis tagab piiramatu üheaegsete kasutajate arvuga ligipääsu piiramatuks ajaks
Frontiers of Computational Fluid Dynamics 2002 2002Suurem pilt
  • Formaat: 524 pages
  • Ilmumisaeg: 05-Dec-2001
  • Kirjastus: World Scientific Publishing Co Pte Ltd
  • ISBN-13: 9789812810793
Teised raamatud teemal:
World Scientific e-raamatudRohkem infot World Scientific e-raamatute kohta
Raamatu kodulehekülg: http://www.worldscientific.com/worldscibooks/10.1142/4887#t=toc
This series of volumes on the Frontiers of Computational Fluid Dynamics was introduced to honor contributors who have made a major impact on the field. The first volume was published in 1994 and was dedicated to Prof Antony Jameson; the second was published in 1998 and was dedicated to Prof Earl Murman. The volume is dedicated to Prof Robert MacCormack.The twenty-six chapters in the current volume have been written by leading researchers from academia, government laboratories, and industry. They present up-to-date descriptions of recent developments in techniques for numerical analysis of fluid flow problems, and applications of these techniques to important problems in industry, as well as the classic paper that introduced the MacCormack scheme to the world.
Dedication v
Contributions of Robert W. MacCormack to Computational Fluid Dynamics
1(26)
Coughey
Hafez
Introduction
1(1)
Overview
2(1)
Technical Contributions
3(14)
Concluding Remarks
17(10)
References
18(9)
The Effect of Viscosity in Hypervelocity Impact Cratering
27(18)
MacCormack
Abstract
27(1)
Introduction
27(1)
The Numerical Method
28(9)
Numerical Calculations
37(3)
Concluding Remarks
40(5)
References
42(3)
The MacCormack Method - Historical Perspective
45(16)
Hung
Deiwert
Inouye
Introduction
45(1)
Evolution of the MacCormack Method
46(4)
Applications
50(7)
Closing Remarks
57(4)
References
58(3)
General Framework for Achieving Textbook Multigrid Efficiency: One-Dimensional Euler Example
61(20)
Thomas
Diskin
Brandt
South
Abstract
61(1)
Introduction
61(2)
General Framework
63(2)
Quasi-One-Dimensional Equations
65(1)
Relaxation Schemes
66(2)
Distributed Relaxation
68(3)
Computational Results
71(3)
Transonic Flows
74(1)
Concluding Remarks
75(6)
References
76(1)
Appendices
77(1)
Conservative Fluxes
77(1)
Distribution Matrices
78(1)
Transonic Shock - ENO Differencing
79(2)
Numerical Solutions of Cauchy-Riemann Equations for Two and Three Dimensional Flows
81(8)
Hafez
Houseman
Introduction
82(1)
Governing Equations and Boundary Conditions
83(1)
Numerical Methods
84(1)
Numerical Results
85(1)
Concluding Remarks
86(1)
Appendix: Multigrid Convergence Results
86(3)
References
86(3)
Efficient High-order Schemes on Non-uniform Meshes for Multi-Dimensional Compressible Flows
89(24)
Lerat
Corre
Hanss
Introduction
89(1)
Euler solver on a regular Cartesian mesh
90(3)
Euler solver on an irregular Cartesian mesh
93(5)
Navier-Stokes solver
98(2)
Numerical experiments
100(5)
Conclusion
105(8)
References
105(8)
Future directions for computing compressible flows: higher-order centering vs multidimensional upwinding
113(16)
Napolitano
Introduction
113(2)
High-order centred numerical method
115(1)
Fluctuation splitting method
116(2)
Results and Discussion
118(6)
Conclusions
124(1)
Acknowledgements
125(4)
References
125(4)
Extension of Efficient Low Dissipation High Order Schemes for 3-D Curvilinear Moving Grids
129(36)
Vinokur
Yee
Introduction
130(4)
Formulation of Equations
134(9)
Numerical Methods
143(12)
Concluding Remarks
155(10)
Acknowledgment
156(1)
Appendix A: The Commutativity of a Class of Numerical Mixed Partial Derivatives
156(4)
Appendix B: Riemann Solver for Non-equilibrium Flow
160(3)
References
163(2)
Fourth Order Methods for the Stokes and Navier-Stokes Equations on Staggered Grids
165(16)
Gustafsson
Nilsson
Introduction
165(2)
The Steady Stokes Equations and Staggered Grids
167(4)
A Fourth Order Method for the Stokes Equations
171(4)
A Fourth Order Method for the Navier-Stokes Equations
175(6)
References
178(3)
Scalable Parallel Implicit Multigrid Solution of Unsteady Incompressible Flows
181(16)
Pankajakshan
Abstract
181(1)
Introduction
182(1)
Basic Unsteady Flow Solver
182(3)
Scalable Parallel Implicit Algorithm
185(3)
Parallel Performance Estimates and Scalability
188(5)
Demonstration: Rudder-Induced Maneuvering Simulation
193(2)
Acknowledgements
195(2)
References
195(2)
Application of Vorticity Confinement to the Prediction of the Flow over Complex Bodies
197(30)
Steinhoff
Introduction
198(1)
Conventional Eulerian Methods
199(1)
Vorticity Confinement
200(6)
Current Results
206(7)
Conclusion
213(14)
References
214(13)
Lattice Boltzmann Simulation of Incompressible Flows
227(46)
Satofuka
Ishikura
Introduction
227(1)
Lattice Boltzmann Method for Two-dimension
228(3)
Two-dimensional Homogeneous Isotropic Turbulence
231(2)
Two-dimensional Channel with Sudden Expansion
233(2)
Lattice Boltzmann Method for Three-dimension
235(1)
Three-dimensional Homogeneous Isotropic Turbulence
236(1)
Three-dimensional Duct Flow
237(2)
Parallelization
239(1)
Conclusion
240(3)
References
240(3)
Numerical Simulation of MHD Effects on Hypersonic Flow of a Weakly Ionized Gas in an Inlet
Agarwal
Deb
Abstract
243(1)
Nomenclature
244(2)
Introduction
246(1)
Governing Equations of Electro-Magnetohydrodynamics
247(2)
Governing Equations in Weak Conservation Law Form
249(3)
Governing Equations in Generalized Coordinates
252(2)
Numerical Method
254(5)
Significant Parameters
259(1)
Numerical Simulation of Supersonic Flow in an Inlet
260(3)
Conclusions
263(1)
Acknowledgements
263(10)
References
263(10)
Progress in Computational Magneto-Aerodynamics
273(26)
Shang
Canupp
Gaitonde
Introduction
273(2)
Governing Equations
275(2)
Numerical Procedures
277(5)
Rankine-Hugoniot Jump Condition
282(3)
Ideal MHD Shock Tube Simulation
285(4)
Hypersonic MHD Blunt Body Simulation
289(4)
Concluding Remarks
293(1)
Acknowledgments
294(1)
References
294(5)
Development of 3D Dragon Grid Method for Complex Geometry
299(20)
Liou
Zheng
Introduction
299(2)
Dragon Grid
301(2)
Three-Dimensional Dragon Grid Generation
303(5)
Flow Solver
308(1)
Test Cases
309(3)
Concluding Remarks
312(7)
Acknowledgments
313(1)
References
314(5)
Application of Multi-Block, Patched Grid Topologies to Navier-Stokes Predictions of the Aerodynamics of Army Shells
319(14)
Sturek
Haroldsen
Introduction
319(1)
Missile Configurations
320(2)
Boundary/Initial Conditions
322(1)
Performance/Convergence Criteria
323(1)
Results
323(1)
Concluding Remarks
324(1)
Acknowledgements
324(9)
References
324(9)
On Aerodynamic Prediction by Solution of the Reynolds-Averaged Navier-Stokes Equations
333(14)
Hall
Introduction
333(3)
The RANS Scheme and the Menter Turbulence Model
336(2)
RANS Results for the Menter Turbulence Model
338(3)
A modification to the Menter turbulence model
341(4)
Concluding Remarks
345(2)
References
346(1)
Advances in Algorithms for Computing Aerodynamic Flows
347(34)
Zingg
De Rango
Pueyo
Introduction
347(2)
Newton-Krylov Algorithm
349(7)
Higher-Order Spatial Discretization
356(10)
Concluding Remarks
366(15)
Acknowledgements
367(1)
References
367(14)
Numerical Simulation of Hypersonic Boundary Layer Stability and Receptivity
381(18)
Zhong
Whang
Ma
Introduction
381(1)
Governing Equations and Numerical Methods
382(1)
Results and Discussion
383(12)
Concluding Remarks
395(4)
References
396(3)
Time-Dependent Simulation of Incompressible Flow in a Turbopump using Overset Grid Approach
399(16)
Kiris
Kwak
Introduction
399(1)
Numerical Method
400(2)
Approach and Computational Models
402(4)
Computed Results
406(7)
Summary
413(1)
Acknowledgements
414(1)
References
414(1)
Aspects of the Simulation of Vortex Flows over Delta Wings
415(28)
Rizzi
Gortz
LeMoigne
Introduction
415(4)
Computational Method
419(2)
Test Cases and Grids
421(5)
Stationary-Wing Computations and Results
426(8)
Preliminary results for Pitching Delta
434(4)
Conclusions and Outlook
438(1)
Acknowledgments
439(4)
References
439(4)
Selected CFD Capabilities at DLR
443(16)
Kordulla
Introduction
443(6)
CFD Developments
449(1)
Recent Applications
449(5)
Where to go
454(1)
Acknowledgements
455(4)
References
455(4)
CFD Applications to Space Transportation Systems
459(16)
Fujii
Introduction
459(1)
Numerical Method
460(1)
Results and Discussion
460(11)
Conclusions
471(1)
Acknowledgement
472(3)
References
472(3)
Multipoint Optimal Design of Supersonic Wings Using Evolutionary Algorithms
475(14)
Obayashi
Takeguchi
Sasaki
Introduction
475(1)
Optimization Method
476(1)
Formulation of the Present Optimization Problem
477(1)
Optimization of a Supersonic Transport Wing
478(2)
Conclusion
480(9)
References
481(8)
Information Science - A New Frontier of CFD
489(4)
Oshima
Oshima
Out of Deterministic Systems into Complex Systems
489(1)
Computers vs Human Brain
490(1)
Information Science
491(2)
Integration of CFD into Aerodynamics Education
493(1)
Murman
Rizzi
Introduction
493(1)
Changes from 1981 to 2000
494(3)
Educational Considerations and Questions
497(2)
Findings from an Informal Survey
499(4)
Examples of Integration
503(2)
Summary
505(1)
Acknowledgements
506(1)
References
506
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