Architecture-adaptable finite element modelling: a case study using ocean circulation simulation

Architecture-adaptable finite element modelling: a case study using ocean circulation simulation

We describe an architecture-adaptable methodology for the parallel implementation of finite element numerical models of physical systems. We use a model of time-dependent ocean currents as our working example. The heart of the computation is the solution of a banded linear system, and we describe an...

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Bibliographische Detailangaben
Hauptverfasser: Kumaran, Santosh, Quinn, Michael J., Miller, Robert N.
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Algorithm design and analysis
Applied computing > Physical sciences and engineering > Earth and atmospheric sciences
Applied computing > Physical sciences and engineering > Engineering
Atmospheric modeling
Computational modeling
Computer simulation
Computer systems organization > Embedded and cyber-physical systems
Computer systems organization > Real-time systems
Computing methodologies > Symbolic and algebraic manipulation > Symbolic and algebraic algorithms > Linear algebra algorithms
Finite element methods
Linear systems
Mathematics of computing > Mathematical analysis > Numerical analysis > Computations on matrices
Numerical models
Oceans
Parallel algorithms
Performance analysis
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Beschreibung
Zusammenfassung:We describe an architecture-adaptable methodology for the parallel implementation of finite element numerical models of physical systems. We use a model of time-dependent ocean currents as our working example. The heart of the computation is the solution of a banded linear system, and we describe an algorithm based on the domain decompositionmethod to solve the banded system. The algorithm is represented in a divide-and-conquer framework facilitates easy implementation of various algorithmic options. The process is straightforward and amenable to automation. We demonstrate the validity of this approach using two radically different target machine, a workstation network and a supercomputer. Our results show very good speedup on both platforms.
DOI:10.1145/224170.224501