High performance scientific and engineering computing : proceedings of the International FORTWIHR Conference on HPSEC, Munich, March 16-18, 1998

Author(s)

    • International FORTWIHR Conference on HPSEC
    • Bungartz, H.-J. (Hans-Joachim)
    • Durst, F.
    • Zenger, Christoph Wilhelm

Bibliographic Information

High performance scientific and engineering computing : proceedings of the International FORTWIHR Conference on HPSEC, Munich, March 16-18, 1998

H.-J. Bungartz, F. Durst, C. Zenger, editors

(Lecture notes in computational science and engineering, 8)

Springer-Verlag, 1999

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Includes bibliographical references

Description and Table of Contents

Description

Since the creation of the term "Scientific Computing" and of its German counterpart "Wissenschaftliches Rechnen" (whoever has to be blamed for that), scientists from outside the field have been confused about the some what strange distinction between scientific and non-scientific computations. And the insiders, i. e. those who are, at least, convinced of always comput ing in a very scientific way, are far from being happy with this summary of their daily work, even if further characterizations like "High Performance" or "Engineering" try to make things clearer - usually with very modest suc cess, however. Moreover, to increase the unfortunate confusion of terms, who knows the differences between "Computational Science and Engineering" , as indicated in the title of the series these proceedings were given the honour to be published in, and "Scientific and Engineering Computing", as chosen for the title of our book? Actually, though the protagonists of scientific com puting persist in its independence as a scientific discipline (and rightly so, of course), the ideas behind the term diverge wildly. Consequently, the variety of answers one can get to the question "What is scientific computing?" is really impressive and ranges from the (serious) "nothing else but numerical analysis" up to the more mocking "consuming as much CPU-time as possible on the most powerful number crunchers accessible" .

Table of Contents

I Fluid Flow.- On the Realistic Performance of Linear Algebra Components in Iterative Solvers.- Applying the Checkpointing Routine treeverse to Discretizations of Burgers' Equation.- Adaptive Grids for Time Dependent Conservation Laws: Theory and Applications in CFD.- Numerical Bifurcation Analysis of Premixed Combustion in Porous Inert Media.- Multigrid Solution of the Incompressible Navier-Stokes Equations and its Application to Parallel Computers.- Simulation of Internal and Free Turbulent Flows.- Application of Parallel Numerical Flow Solvers Invoking Advanced Turbulence-Transport Models to Aircraft Components.- Solution of Coupled Problems by Parallel Multigrid.- Coupled Numerical Computations of the Fluid Damped Oscillations of a Lamina.- Efficient Treatment of Complicated Geometries and Moving Interfaces for CFD Problems.- II Dynamic Systems and Optimal Control.- Very Low Thrust Trajectory Optimization.- Mechanical Multibody Systems with Deformable Components.- Real Time Simulation and Online Control for Virtual Test Drives of Cars.- Numerical Simulation of Vibrations for the Design of a Rear Axle.- Flight Tests with Computer Generated Synthetic Vision.- Flight Path Optimization with a New Homotopy Method for Reducing Safety Hazards in Microbursts.- Integrated User Environment for the Numerical Solution of Optimal Control Problems.- Simulation and Optimization of Logistic Processes Involving Sloshing Media.- Numerical Simulation and Optimal Control of Air Separation Plants.- Advanced Extrapolation Methods for Large Scale Differential Algebraic Problems.- III Melting, Coating, and Crystal Growth.- On the Generation and Spreading of 'Finger' Instabilities in Film Coating Processes.- CrysVUN++, a Powerful Computer Code for Global Thermal Modelling of Industrial Crystal Growth Processes.- 3D Adaptive Unstructured Grid Solver: Application to Flow and GaAs Deposition in the Planetary Reactor (TM).- Direct Navier-Stokes Simulations of Turbulent Czochralski Flows.- IV Semiconductors and Circuits.- Advanced Models, Applications, and Software Systems for High Performance Computing - Application in Microelectronics.- Numerical Simulation of Microstructured Semiconductor Devices, Transducers, and Systems.- Parallel Multigrid Methods for the Continuity Equations in Semiconductor Device Simulation.- Partitioning Strategies in Circuit Simulation.- A New Stochastic Integration Scheme for the Efficient Solution of Randomly Disturbed Circuits.- Eigenvalue Solvers for Electromagnetic Fields in Cavities.- Remarks on the Convex Analysis of the Energy Model of Semiconductor Devices.- Analysis of Electromechanical Microdevices Using Coupled FEM-BEM Based on the TP2000 CAD Platform.- Numerical Analysis of Distributed Inductive Parasitics in High Power Bus Bars.- Low Pressure Discharges in Plasma Reactors: Modelling and Computer-Aided Diagnostics.- V HPSC in Physics and Chemistry.- Numerical Fluid Dynamics in Astrophysics with Smoothed Particle Hydrodynamics.- Parallel Computation of Multi-Dimensional Neutron and Photon Transport in Inhomogeneous Media.- Quantum Chemistry on Parallel Computers: Concepts and Results of a Density Functional Method.- Future Trends in HPSC.- Technological Trends and their Impact on the Future of Supercomputers.

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