Publication result detail

On computational stability of explicit schemes in nonlinear engineering dynamics

VALA, J.; JAROŠOVÁ, P.

Original Title

On computational stability of explicit schemes in nonlinear engineering dynamics

English Title

On computational stability of explicit schemes in nonlinear engineering dynamics

Type

Paper in proceedings (conference paper)

Original Abstract

Physical analysis of problems of engineering dynamics leads typically to hyperbolic systems of partial differential equations of evolution of 2nd order with some nonlinear terms, supplied with Dirichlet and Neumann boundary conditions together with some interface ones and with Cauchy initial conditions. Their numerical treatment needs coupling the finite element (or similar) method with the method of discretization in time. The preference of distributed and parallel computations for large problems, e. g. of multiple contacts of moving deformable bodies, stimulates the analysis of convergence and stability properties of explicit integration schemes, as simple, e ective and robust as possible. This paper demonstrates such research direction, significant for practical calculations, on the conditional stability of a model simple explicit algorithm, motivated by the central difference method, implemented ad hoc e. g. in the LS-DYNA software package.

English abstract

Physical analysis of problems of engineering dynamics leads typically to hyperbolic systems of partial differential equations of evolution of 2nd order with some nonlinear terms, supplied with Dirichlet and Neumann boundary conditions together with some interface ones and with Cauchy initial conditions. Their numerical treatment needs coupling the finite element (or similar) method with the method of discretization in time. The preference of distributed and parallel computations for large problems, e. g. of multiple contacts of moving deformable bodies, stimulates the analysis of convergence and stability properties of explicit integration schemes, as simple, e ective and robust as possible. This paper demonstrates such research direction, significant for practical calculations, on the conditional stability of a model simple explicit algorithm, motivated by the central difference method, implemented ad hoc e. g. in the LS-DYNA software package.

Keywords

finite difference method; computational dynamics

Key words in English

finite difference method; computational dynamics

Authors

VALA, J.; JAROŠOVÁ, P.

RIV year

2024

Released

01.09.2023

Publisher

American Institute of Physics

Location

Melville (USA)

ISBN

978-0-7354-4182-8

Book

ICNAAM 2021 Proceedings

Volume

2849

Number

1

Pages from

370004-1

Pages to

370004-4

Pages count

4

URL

https://pubs.aip.org/aip/acp/article/2849/1/370004/2909204/