High Performance Computing in Science and Engineering, Munich 2004: Transactions of the Second Joint HLRB and KONWIHR Status and Result Workshop, March 2-3, 2004, Technical University of Munich, and Leibniz-Rechenzentrum Munich, GermanySiegfried Wagner, Werner Hanke, Arndt Bode, Franz Durst Leading-edge research groups in the field of scientific computing present their outstanding projects using the High Performance Computer in Bavaria (HLRB), Hitachi SR8000-F1, one of the top-level supercomputers for academic research in Germany. The projects address modelling and simulation in the disciplines Biosciences, Chemistry, Chemical Physics, Solid-State Physics, High-Energy Physics, Astrophysics, Geophysics, Computational Fluid Dynamics, and Computer Science. The authors describe their scientific background, their resource requirements with respect to top-level supercomputers, and their methods for efficient utilization of the costly high-performance computing power. Contributions of interdisciplinary research projects that have been supported by the Competence Network for Scientific High Performance Computing in Bavaria (KONWIHR) complete the broad range of supercomputer research and applications covered by this volume. |
Contents
II | 3 |
III | 27 |
IV | 37 |
V | 51 |
VI | 53 |
VII | 63 |
VIII | 77 |
IX | 93 |
XXVII | 273 |
XXVIII | 285 |
XXIX | 289 |
XXX | 301 |
XXXI | 309 |
XXXII | 319 |
XXXIII | 329 |
XXXIV | 339 |
X | 107 |
XI | 119 |
XII | 133 |
XIV | 145 |
XV | 157 |
XVI | 169 |
XVII | 179 |
XIX | 187 |
XX | 189 |
XXI | 199 |
XXII | 211 |
XXIII | 225 |
XXIV | 237 |
XXV | 245 |
XXVI | 261 |
XXXV | 349 |
XXXVI | 363 |
XXXVII | 375 |
XXXVIII | 383 |
XXXIX | 385 |
XLI | 395 |
XLIII | 401 |
XLIV | 409 |
XLV | 419 |
XLVI | 431 |
XLVII | 443 |
XLVIII | 445 |
XLIX | 459 |
Other editions - View all
Common terms and phrases
airfoil algorithm application architectures atoms benchmark boundary conditions boundary layer calculations channel flow Chem cluster component configuration convergence correlation CPMD Cray X1 density Direct numerical simulation distribution domain dynamics efficient electronic energy equation fermions fluid function geometry graphs High Performance Computing Hitachi Hitachi SR8000 Hubbard Hubbard model implementation interaction interface Itanium lattice Boltzmann lattice Boltzmann methods lattice QCD Lett magnetic field matrix MCTDH mechanism memory method mode molecular molecular dynamics molecules monitoring München Munich nodes number of processors numerical simulation obtained OpenMP Opteron optimization parallel parameters particles phase Phys physics plane potential Power4 problem propagation pseudopotentials quantum quark quark masses RAXML Reynolds number Reynolds stress rotation scalar scaling separation bubble solver spanwise speedup step stress structure supercomputer symmetry temperature tensor tion transition values vector velocity visualization wave Xeon