Scheduling of tasks in the parareal algorithm

► A detailed study of scheduling of tasks in the parareal algorithm. ► Two new algorithms are proposed. ► Significant improvement of efficiency compared to usual parareal algorithm. ► Discussion of the promise of the parareal algorithm for use on computational grids. Parallelization of partial diffe...

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Vydáno v:Parallel computing Ročník 37; číslo 3; s. 172 - 182
Hlavní autor: Aubanel, Eric
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier B.V 01.03.2011
Témata:
Algorithms
Computation
Computer simulation
Numerical solution of PDEs
Parallel processing
Parareal algorithm
Partial differential equations
Processors
Scheduling
Tasks
Time parallelization
Numerical solution of PDEs
Time parallelization
Parareal algorithm
ISSN:0167-8191, 1872-7336
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Shrnutí:► A detailed study of scheduling of tasks in the parareal algorithm. ► Two new algorithms are proposed. ► Significant improvement of efficiency compared to usual parareal algorithm. ► Discussion of the promise of the parareal algorithm for use on computational grids. Parallelization of partial differential equations (PDEs) by time decomposition has attracted much interest, mainly due to its potential to enable very long time simulations beyond what is possible using spatial domain decomposition. However, there has only been limited performance analysis of the parareal algorithm in the literature, ignoring the efficient scheduling of tasks. This paper presents a detailed study of the scheduling of tasks in the parareal algorithm that achieves significantly better efficiency than the usual algorithm. Two algorithms are proposed, one which uses a manager–worker paradigm with overlap of sequential and parallel phases, and a second that is completely distributed. Experiments were conducted with the 2D heat equation. It was found that the rate of convergence decreases as the number of processors increases, in the case of strong scaling (fixed time interval). However, for weak scaling results the rate of convergence was unaffected by the number of processors. The results of this paper suggest that the parareal algorithm is a promising approach to solving long time evolution problems, particularly when the goal is simulation of longer times using more processors. It also exhibits characteristics that make it particularly suitable for execution on heterogeneous computational grids, such as low communication overhead and easy accommodation of different processor and network speeds.
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ISSN:0167-8191
1872-7336
DOI:10.1016/j.parco.2010.10.004