Earthquake ground motion modeling on parallel computers

Earthquake ground motion modeling on parallel computers

We describe the design and discuss the performance of a parallel elastic wave propagation simulator that is being used to model and study earthquake-induced ground motion in large sedimentary basins. The components of the system include mesh generators, a mesh partitioner, a parceler, and a parallel...

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Bibliographic Details
Published in:Conference on High Performance Networking and Computing: Proceedings of the 1996 ACM/IEEE conference on Supercomputing (CDROM); 01-01 Jan. 1996 pp. 13 - es
Main Authors: Bao, Hesheng, Bielak, Jacobo, Ghattas, Omar, Kallivokas, Loukas F., O'Hallaron, David R., Shewchuk, Jonathan R., Xu, Jifeng
Format: Conference Proceeding
Language:English
Published: Washington, DC, USA IEEE Computer Society 17-11-1996
Series:ACM Conferences
Subjects:
Applied computing > Physical sciences and engineering
Computer systems organization > Architectures > Parallel architectures
Computer systems organization > Dependable and fault-tolerant systems and networks
Computing methodologies > Modeling and simulation
General and reference > Cross-computing tools and techniques > Performance
Networks > Network performance evaluation
Software and its engineering > Software notations and tools > Compilers
Theory of computation > Models of computation
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Summary:We describe the design and discuss the performance of a parallel elastic wave propagation simulator that is being used to model and study earthquake-induced ground motion in large sedimentary basins. The components of the system include mesh generators, a mesh partitioner, a parceler, and a parallel code generator, as well as parallel numerical methods for applying seismic forces, incorporating absorbing boundaries, and solving the discretized wave propagation problem. We discuss performance on the Cray T3D for unstructured mesh wave propagation problems of up to 14 million tetrahedra. By paying careful attention to each step of the process, we obtain excellent performance despite the highly irregular structure of the coefficient matrices of the problem. The mesh generator, partitioner, parceler, and code generator have been incorporated into an integrated toolset/compiler. This system, called Archimedes, automates the solution of unstructured mesh PDE problems on parallel computers, and is being used for other unstructured mesh applications beyond ground motion modeling.
Bibliography:SourceType-Conference Papers & Proceedings-1
ObjectType-Conference Paper-1
content type line 25
ISBN:0897918541
9780897918541
DOI:10.1145/369028.369053