An efficient algorithm for the parallel solution of high-dimensional
  differential equations

Benner; Bjorhus; Burrage; Cong Liu; Henzinger; Holmes; Jeong; Leimkuhler; Leimkuhler; Lumsdaine; Marsan; Marsan; Marsan; Marsan; McMillan; Michael Dellnitz; Molla-Hosseini; Palladino; Ren; Rowley; Stefan Klus; Stoer; Trefethen; Tuhin Sahai; von Luxburg; White; Woodside

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An efficient algorithm for the parallel solution of high-dimensional differential equations

Authors: Benner
Bjorhus
Burrage
Cong Liu
Henzinger
Holmes
Jeong
Leimkuhler
Leimkuhler
Lumsdaine
Marsan
Marsan
Marsan
Marsan
McMillan
Michael Dellnitz
Molla-Hosseini
Palladino
Ren
Rowley
Stefan Klus
Stoer
Trefethen
Tuhin Sahai
von Luxburg
White
Woodside
Publication date: 26 October 2010
Publisher: 'Elsevier BV'
Doi

Abstract

The study of high-dimensional differential equations is challenging and difficult due to the analytical and computational intractability. Here, we improve the speed of waveform relaxation (WR), a method to simulate high-dimensional differential-algebraic equations. This new method termed adaptive waveform relaxation (AWR) is tested on a communication network example. Further we propose different heuristics for computing graph partitions tailored to adaptive waveform relaxation. We find that AWR coupled with appropriate graph partitioning methods provides a speedup by a factor between 3 and 16

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