Parallel Computational Fluid Dynamics 2004: Multidisciplinary ApplicationsGabriel Winter, Jacques Periaux, Pat Fox, A. Ecer, N. Satofuka Parallel CFD 2004, the sixteenth international conference on Parallel Computational Fluid Dynamics and other modern scientific domains, has been held since May 24th till May 27th, 2004 in Las Palmas de Gran Canaria, Spain. The specialized, high-level Parallel CFD conferences are organised on travelling locations all over the world, yearly because of multidisciplinary subject of parallel CFD and its rapidly evolving nature. The conference featured 8 invited lectures, 3 Mini Symposia, contributed papers and one Tutorial & Short Course. More than 80 multi-disciplinary presentations of the Parallel CFD had been presented, with participants from 17 countries. The sessions involved contributed papers on many diverse subjects including turbulence, complex flows, unstructured and adaptive grids, industrial applications, developments in software tools and environments as parallel optimization tools. This Book presents an up-to-date overview of the state of the art in parallel computational fluid dynamics. - Report on current research in the field. - Researchers around the world are included. - Subject is important to all interested in solving large fluid dynamics problems. - It is of interest to researchers in computer science, engineering and physical sciences. - It is an interdisciplinary activity. Contributions include scientists with a variety of backgrounds. - It is an area which is rapidly changing. |
Contents
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S Peigin and B Epstein Massive Parallelization as Principal Technology for Constrained Optimization of Aerodynamic Shapes | 33 |
J M McDonough and T Yang Parallel Performance of a New Model for Wildland Fire Spread Predictions | 45 |
M Soria F X Trias CD PérezSegarra and A Oliva Direct Numerical Simulation of Turbulent Natural Convection Flows on PC Clusters Using a Fourth... | 53 |
W LoandCA Lin A Near Wall Pressure Treatment for Large Eddy Simulation | 61 |
I Boursier D TromeurDervout and Y Vassilevsky AitkenSchwarz Methods with Non Matching Finite Elements and Spectral Elements Grids for the Pa... | 69 |
C Ciortan C Guedes Soares J Wanderley and C Levi Calculation of the Flow Around Ship Hulls Using a Parallel CFD Code | 215 |
A I Sukhinov and A A Sukhinov 3D Model of DiffusionAdvectionAggregation Suspensions in Water Basins and Its Parallel Realization | 223 |
A I Sukhinov and A A Sukhinov Reconstruction of 2001 Ecological Disaster in the Azov Sea on the Basis of Precise Hydrophysics Models | 231 |
I A Graur T A Kudryashova and S V Polyakov Modeling of Flow for Radiative Transport Problems | 239 |
S M Bakhrakh O B Drennov T A Goreva A L Mikhailov P N Nizovtsev and E V Shuvalova V F Spiridonov and N A Volodina Numerical Simulation... | 247 |
BN Chetverushkin and N Yu Romanyukha Kinetic and Lattice Boltzmann Schemes | 257 |
R K Agarwal Lattice Boltzmann Simulations of Magnetohydrodynamic Slip Flow in MicroChannels | 263 |
G Brenner and A AlZoubi Application of the Lattice Boltzmann Method for the Estimation of Permeabilities in Complex Structures | 271 |
A Performance Point of View | 77 |
V Ivannikov S Gaissaryan A Avetisyan and V Padaryan Checkpointing improvement in ParJava environment | 85 |
R Sentis and F Duboc Coupling Hydrodynamics with a Paraxial Solver for Laser Propagation The HERA Plateform for LaserPlasma interaction | 93 |
M Borchardt H Leyh J Riemann and R Schneider Linux Cluster Computing for Stellarator Studies | 99 |
A V Alexandrov V G Bobkov and T K Kozubskaya DNS Simulation of Acoustic Wave Damping in a Liner Element | 105 |
F X Trias M Soria O Lehmkuhl and CD PérezSegarra An Efficient Direct Algorithm for the Solution of the FourthOrder Poisson Equation on Loosel... | 113 |
H Nishida H Yoshioka andM Hatta Higher Order Parallel DNS of Incompressible Turbulence Using Compressible NavierStokes Equations | 121 |
K Chiba S Obayashi and K Nakahashi Tradeoff Analysis of Aerodynamic Wing Design for RLV | 129 |
I H Tuncer and M Kaya Parallel Optimization of Flapping Airfoils in a Biplane Configuration for Maximum Thrust | 137 |
L González EJ Whitney K Srinivas J Périaux CFD Design in Aeronautics Using a Robust Multilevel Parallel Evolutionary Optimiser | 145 |
M Yamakawa and K Matsuno Solutions of the Flow Field on Unstructured MovingPatchedGrid in a Parallel Environment | 155 |
K Nakahashi andLS Kim HighDensity Mesh Computations of Airfoil Flows by BuildingCube Method | 163 |
S N Boldyrev On Using the Multilevel Approach in Partitioning Big Unstructured Meshes | 171 |
H Tomita M Satoh and T Nasuno A Stretched Icosahedral Grid for the Global Cloud Resolving Model | 177 |
ENVIRONMENTAL FLOWS ECOLOGY PROBLEMS | 183 |
B Galván B González A Padrón H Carmona and G Winter Optimal Placement of Wastewater Outfalls Using an Internetbased Distributed Computing ... | 191 |
Modellization of Water Exchange at the Strait of Gibraltar | 199 |
M Zijlema Parallelization of a Nearshore Wind Wave Model for Distributed Memory Architectures | 207 |
X J Gu D R Emerson D Bradley and P H Gaskell Numerical Modeling of Turbulent NonPremixed Methane Jet Flames in a Crosswind | 279 |
É Laucoin and C Calvin A Parallel FrontTracking Method for TwoPhase Flows Simulations | 289 |
BN Chetverushkin N G Churbanova and M A Trapeznikova Parallel Simulation of Low Mach Number Flows Based on the Quasi Gas Dynamic Mode... | 297 |
A Highly Accurate Method With a Fully Meshless Formulation | 305 |
K Shimano K Okudera T Anaguchi N Utsumi M Saito C Sumie and Y Enomoto Parallel Computing of Flow in Centrifugal Fan Volute Using Contrav... | 313 |
Ø Staff and S Ø Wille The Efficiency of a Parallel ILU Preconditioner for Finite Element Solutions of the NavierStokes Equations | 321 |
J Sahu and K R Heavey High Performance Parallel Computing CFD Simulations of Projectiles with Flow Control | 329 |
BN Chetverushkin VA Gasilov SV Polyakov MV Iakobovski EL Kartashera IV Abalakin IV Popov NYu Romanyukha SA Sukov andAS Minkin CF... | 339 |
Computing 339 M Kremenetsky and T Larsson Numerical Studies on a ccNUMA Computer Architecture for a Large Scale Race Car Aerodynamics S... | 345 |
M Kremenetsky and T Larsson Numerical Studies on a ccNUMA Computer Architecture for a Large Scale Race Car Aerodynamics Simulation | 353 |
A Frullone and D TromeurDervout A Ghost Cell Immersed Boundary Method Coupled with Aitken Schwarz DDM for Computation of LiquidLiquid... | 361 |
D TromeurDervout Adaptive Time Domain Decomposition for Systems of ODEs on Grid Architecture | 369 |
K Matsuno Flexible and Efficient Parallel Computation for Complex Flows Using BuildingMultiBlock and Block Decomposition Method | 377 |
Y Kim S H Park K W Cho andJ H Kwon Turbulent Flow Simulations Using the Parallelized Multigrid NavierStokes Solver | 383 |
RU Payli E Yilmaz A Ecer HU Akay andS Chien DLB A Dynamic Load Balancing Tool for Grid Computing | 387 |
S Y Chien L Giavelli A Ecer and H U Akay Security Considerations in the Distributed Parallel Computation Environment | 395 |
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Parallel Computational Fluid Dynamics: Multidisciplinary Applications ... Gabriel Winter No preview available - 2005 |
Common terms and phrases
accuracy aerodynamic AIAA airfoil Applications G approach Azov Sea B.V. All rights block boundary conditions calculation cells checkpoint coefficients communication compressible Computational Fluid Dynamics configuration convection convergence density developed Direct Numerical Simulation discretization domain decomposition Ecer Elsevier B.V. evaluated Evolutionary Algorithms flow field Fox Editors gas dynamic geometry grid computing grid points incompressible incompressible flow interface iterations lattice Boltzmann lattice Boltzmann method layer linear load balancing Mach number matrix memory mesh Multidisciplinary Applications Navier-Stokes equations nodes number of processors numerical simulation obtained OpenMP optimization Parallel CFD Parallel Computational Fluid parallel efficiency parallel performance parallel program parameters particles partitioning PC cluster Periaux Poisson equation preconditioner present pressure problem Reynolds number rights reserved Satofuka scalability scheme solution solve solver space step structure subdomains surface technique transonic unsteady unstructured variables vector velocity viscous vorticity