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Computers and Concrete Volume 2, Number 5, October 2005 , pages 345-366 DOI: https://doi.org/10.12989/cac.2005.2.5.345 |
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Assessment of computational performance for a vector parallel implementation: 3D probabilistic model discrete cracking in concrete |
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Carmen N. M. Paz, Jose L. D. Alves and Nelson F. F. Ebecken
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Abstract | ||
This work presents an assessment of the computational performance of a vector-parallel implementation of probabilistic model for concrete cracking in 3D. This paper shows the continuing efforts towards code optimization as reported in earlier works Paz, et al. (2002a,b and 2003). The probabilistic crack approach is based on the direct Monte Carlo method. Cracking is accounted by means of 3D interface elements. This approach considers that all nonlinearities are restricted to interface elements modeling cracks. The heterogeneity governs the overall cracking behavior and related size effects on concrete fracture. Computational kernels in the implementation are the inexact Newton iterative driver to solve the non-linear problem and a preconditioned conjugate gradient (PCG) driver to solve linearized equations, using an element by element (EBE) strategy to compute matrix-vector products. In particular the paper analyzes code behavior using OpenMP directives in parallel vector processors (PVP), such as the CRAY SV1 and CRAY T94. The impact of the memory architecture on code performance, and also some strategies devised to circumvent this issue are addressed by numerical experiment. | ||
Key Words | ||
high performance computing; openMP directives; vector-parallel performance analysis; non linear analysis; probabilistic discrete cracking in concrete; 3D finite elements; size effects; heterogeneity material. | ||
Address | ||
LAMCE/COPPE/UFRJ, Program of Civil Engineering, PO Box 68552, 21944-900, Brazil | ||