## High Performance Computing in Science and Engineering ’98: Transactions of the High Performance Computing Center Stuttgart (HLRS) 1998The book contains reports about the most significant projects from science and industry that are using the supercomputers of the Federal High Performance Computing Center Stuttgart (HLRS). These projects are from different scientific disciplines, with a focus on engineering, physics and chemistry. They were carefully selected in a peer-review process and are showcases for an innovative combination of state-of-the-art physical modeling, novel algorithms and the use of leading-edge parallel computer technology. As HLRS is in close cooperation with industrial companies, special emphasis has been put on the industrial relevance of results and methods. |

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### Contents

13 | |

Dynamical Behaviour of Persistent Spins in the Triangular Potts Model | 26 |

Interacting ParticleLiquid Systems | 54 |

Parallel Seismic Data Processing | 73 |

Solid State Physics | 93 |

SU2spin Invariant Auxiliary Field Quantum MonteCarlo Algorithm | 105 |

Numerical study of spincharge separation in one dimension | 121 |

Towards a TimeDependent DensityFunctional Description of Multiple | 142 |

T J Hüttl and R Friedrich | 236 |

Parallelization of the CFD Code KAPPA for Distributed Memory Computers | 252 |

Unsteady Flow Simulation in an Axial Flow Turbine Using | 269 |

NavierStokesCalculations of the Flow around a Helicopter Fuselage | 295 |

Parallel multilevel algorithms for solving the incompressible | 308 |

A Parallel SoftwarePlatform for Solving Problems of Partial Differential | 326 |

Reacting Flows | 341 |

Engineering and ComputerScience | 375 |

Chemistry and HighPerformance Computing | 159 |

T Detmer P Schmelcher and L S Cederbaum | 175 |

Computational Fluid Dynamics | 196 |

High Performance Computing of Turbulent Flow in Complex | 198 |

DNS of PointSource Induced Transition in an Airfoil BoundaryLayer Flow | 213 |

H Finckh | 388 |

Parallel SPH on CRAY T3E and NECSX4 Using | 396 |

PISA Parallel Image Segmentation Algorithms | 410 |

Construction of Large Permutation Representations for Matrix Groups | 430 |

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### Common terms and phrases

algorithm axial block boundary conditions boundary layer calculated coarse grid components convection correlation corresponding Cray T3E density Dirac operator direct numerical simulation discretization distribution domain double coset dynamics efficient electronic elements energy equations experimental field strengths Figure finite fluid function furnace geometry global grid points hash table high performance computers HLRS Hubbard model implementation integration interaction interface internuclear iterations lattice Lett linear magnetic field matrix memory mesh method MFLOP momentum multigrid multigrid method Navier-Stokes Navier-Stokes equations NEC SX-4 nodes number of processors operation parallel computers parallelisation parameters particles Phys physical pipe Potts model pressure problem quantum Reynolds number rotating rotor scale second stator shows solution solved solver spatial speedup spin stator step strong generating set structure Stuttgart surface temperature time-dependent tion turbulent flow unsteady values vector velocity watershed algorithm wave