Your search keyword '"Beams, Natalie"' showing total 3 results

1. Performance Portable Solid Mechanics via Matrix-Free $p$-Multigrid

Author

Brown, Jed, Barra, Valeria, Beams, Natalie, Ghaffari, Leila, Knepley, Matthew, Moses, William, Shakeri, Rezgar, Stengel, Karen, Thompson, Jeremy L., and Zhang, Junchao

Subjects

G.4, FOS: Computer and information sciences, J.2, D.1.3, G.1.5, G.1.8, G.1.10, J.6, Numerical Analysis (math.NA), Computational Engineering, Finance, and Science (cs.CE), Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science::Mathematical Software, FOS: Mathematics, Computer Science - Mathematical Software, Mathematics - Numerical Analysis, Distributed, Parallel, and Cluster Computing (cs.DC), Computer Science - Computational Engineering, Finance, and Science, Mathematical Software (cs.MS)

Abstract

Finite element analysis of solid mechanics is a foundational tool of modern engineering, with low-order finite element methods and assembled sparse matrices representing the industry standard for implicit analysis. We use performance models and numerical experiments to demonstrate that high-order methods greatly reduce the costs to reach engineering tolerances while enabling effective use of GPUs; these data structures also offer up to 2x benefit for linear elements. We demonstrate the reliability, efficiency, and scalability of matrix-free $p$-multigrid methods with algebraic multigrid coarse solvers through large deformation hyperelastic simulations of multiscale structures. We investigate accuracy, cost, and execution time on multi-node CPU and GPU systems for moderate to large models (millions to billions of degrees of freedom) using AMD MI250X (OLCF Crusher), NVIDIA A100 (NERSC Perlmutter), and V100 (LLNL Lassen and OLCF Summit), resulting in order of magnitude efficiency improvements over a broad range of model properties and scales. We discuss efficient matrix-free representation of Jacobians and demonstrate how automatic differentiation enables rapid development of nonlinear material models without impacting debuggability and workflows targeting GPUs. The methods are broadly applicable and amenable to common workflows, presented here via open source libraries that encapsulate all GPU-specific aspects and are accessible to both new and legacy code, allowing application code to be GPU-oblivious without compromising end-to-end performance on GPUs.

Published

2022

2. An iterative solver for the HPS discretization applied to three dimensional Helmholtz problems

Author

Lorca, José Pablo Lucero, Beams, Natalie, Beecroft, Damien, and Gillman, Adrianna

Subjects

FOS: Computer and information sciences, 65N22, 65N35, 65N55, 65F05, Computer Science - Distributed, Parallel, and Cluster Computing, FOS: Mathematics, MathematicsofComputing_NUMERICALANALYSIS, Numerical Analysis (math.NA), Distributed, Parallel, and Cluster Computing (cs.DC), Mathematics - Numerical Analysis

Abstract

This manuscript presents an efficient solver for the linear system that arises from the Hierarchical Poincar\'e-Steklov (HPS) discretization of three dimensional variable coefficient Helmholtz problems. Previous work on the HPS method has tied it with a direct solver. This work is the first efficient iterative solver for the linear system that results from the HPS discretization. The solution technique utilizes GMRES coupled with a locally homogenized block-Jacobi preconditioner. The local nature of the discretization and preconditioner naturally yield the matrix-free application of the linear system. Numerical results illustrate the performance of the solution technique. This includes an experiment where a problem approximately 100 wavelengths in each direction that requires more than a billion unknowns to achieve approximately 4 digits of accuracy takes less than 20 minutes to solve.

Published

2021

3. GPU Algorithms for Efficient Exascale Discretizations

Author

Abdelfattah, Ahmad, Barra, Valeria, Beams, Natalie, Bleile, Ryan, Brown, Jed, Camier, Jean-Sylvain, Carson, Robert, Chalmers, Noel, Dobrev, Veselin, Dudouit, Yohann, Fischer, Paul, Karakus, Ali, Kerkemeier, Stefan, Kolev, Tzanio, Lan, Yu-Hsiang, Merzari, Elia, Min, Misun, Phillips, Malachi, Rathnayake, Thilina, Rieben, Robert, Stitt, Thomas, Tomboulides, Ananias, Tomov, Stanimire, Tomov, Vladimir, Vargas, Arturo, Warburton, Tim, and Weiss, Kenneth

Subjects

FOS: Computer and information sciences, Computer Science - Distributed, Parallel, and Cluster Computing, FOS: Mathematics, Computer Science - Mathematical Software, Mathematics - Numerical Analysis, Distributed, Parallel, and Cluster Computing (cs.DC), Numerical Analysis (math.NA), Mathematical Software (cs.MS)

Abstract

In this paper we describe the research and development activities in the Center for Efficient Exascale Discretization within the US Exascale Computing Project, targeting state-of-the-art high-order finite-element algorithms for high-order applications on GPU-accelerated platforms. We discuss the GPU developments in several components of the CEED software stack, including the libCEED, MAGMA, MFEM, libParanumal, and Nek projects. We report performance and capability improvements in several CEED-enabled applications on both NVIDIA and AMD GPU systems.

Published

2021