Solution of Superlarge Problems in Computational Mechanics

  • James H. Kane
  • Arthur D. Carlson
  • Donald L. Cox

Table of contents

  1. Front Matter
    Pages i-viii
  2. Farzin Shakib, Thomas J. R Hughes, Zdenëk Johan
    Pages 1-33
  3. Jeffrey K. Bennighof, Michael C. Sciascia
    Pages 35-48
  4. J. Demmel, J. Dongarra, J. DuCroz, A. Greenbaum, S. Hammarling, D. Sorensen
    Pages 67-71
  5. John E. Bussoletti, Forrester T. Johnson, David P. Young, Robin G. Melvin, Richard H. Burkhart, Michael B. Bieterman et al.
    Pages 95-124
  6. Daniel T. Valentine, A. Gaber Mohamed
    Pages 167-181
  7. Gary M. Johnson
    Pages 267-283
  8. Back Matter
    Pages 303-305

About this book

Introduction

There is a need to solve problems in solid and fluid mechanics that currently exceed the resources of current and foreseeable supercomputers. The issue revolves around the number of degrees of freedom of simultaneous equations that one needs to accurately describe the problem, and the computer storage and speed limitations which prohibit such solutions. The goals of tHis symposium were to explore some of the latest work being done in both industry and academia to solve such extremely large problems, and to provide a forum for the discussion and prognostication of necessary future direc­ tions of both man and machine. As evidenced in this proceedings we believe these goals were met. Contained in this volume are discussions of: iterative solvers, and their application to a variety of problems, e.g. structures, fluid dynamics, and structural acoustics; iterative dynamic substructuring and its use in structural acoustics; the use of the boundary element method both alone and in conjunction with the finite element method; the application of finite difference methods to problems of incompressible, turbulent flow; and algorithms amenable to concurrent computations and their applications. Furthermore, discussions of existing computational shortcomings from the big picture point of view are presented that include recommendations for future work.

Keywords

acoustics algebra boundary element method computational mechanics finite element method flow fluid fluid mechanics future industry linear algebra modeling partial differential equation structural mechanics turbulent flow

Editors and affiliations

  • James H. Kane
    • 1
  • Arthur D. Carlson
    • 2
  • Donald L. Cox
    • 2
  1. 1.Clarkson UniversityPotsdamUSA
  2. 2.Naval Underwater Systems CenterNew LondonUSA

Bibliographic information

  • DOI https://doi.org/10.1007/978-1-4613-0535-4
  • Copyright Information Springer-Verlag US 1989
  • Publisher Name Springer, Boston, MA
  • eBook Packages Springer Book Archive
  • Print ISBN 978-1-4612-7854-2
  • Online ISBN 978-1-4613-0535-4
  • About this book