Steering in computational science: mesoscale modelling and simulation

AR Porter; Chapman S.; DeFanti T.; Foster I.; Foster I.; Frisch U.; Gompper G.; Gonzalez-Segredo N.; J Chin; J Harting; Jenness T.; Liboff R. L.; Love P. J.; Love P. J.; Ou W.; PV Coveney; Reichl L. E.; Rothman D. H.; S Jha; Schroeder W.; SM Pickles; Sued S.; Van Wijk J. J.

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Steering in computational science: mesoscale modelling and simulation

Authors: AR Porter
Chapman S.
DeFanti T.
Foster I.
Foster I.
Frisch U.
Gompper G.
Gonzalez-Segredo N.
J Chin
J Harting
Jenness T.
Liboff R. L.
Love P. J.
Love P. J.
Ou W.
PV Coveney
Reichl L. E.
Rothman D. H.
S Jha
Schroeder W.
SM Pickles
Sued S.
Van Wijk J. J.
Publication date: 1 January 2003
Publisher: 'Informa UK Limited'
Doi

Abstract

This paper outlines the benefits of computational steering for high performance computing applications. Lattice-Boltzmann mesoscale fluid simulations of binary and ternary amphiphilic fluids in two and three dimensions are used to illustrate the substantial improvements which computational steering offers in terms of resource efficiency and time to discover new physics. We discuss details of our current steering implementations and describe their future outlook with the advent of computational grids.Comment: 40 pages, 11 figures. Accepted for publication in Contemporary Physic

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