SPARTA Kokkos: A Performance Portable DSMC Code for Re-entry and Turbulence Modeling
Abstract not provided.
Publications
Parallel Algorithms for Hyperdynamics in LAMMPS
Abstract not provided.
Coupled Magnetic Spin Dynamics and Molecular Dynamics in a Massively Parallel Framework
Abstract not provided.
30 Yeras of HPC from Gigaflops to Exaflops: No Science left behind or thinning the herd?
Abstract not provided.
Coupled Magnetic Spin Dynamics and Molecular Dynamics in a Massively Parallel Framework
Abstract not provided.
Parallel Algorithms for Hyperdynamics in LAMMPS
Abstract not provided.
SPARTA: An Open-Source DSMC Code for Turbulence and Re-entry Modeling
Abstract not provided.
Challenges for Materials Modeling at the Atomic and Meso Scales
Abstract not provided.
Large-Scale DSMC Simulations ... Part 2: Computational aspects [PowerPoint]
Abstract not provided.
Molecular-Level Simulations of the Turbulent Taylor-Green Flow
Abstract not provided.
FFTs for (mostly) Particle Codes within the DOE Exascale Computing Project
Abstract not provided.
Particles HPC and the Ukulele Syndrome
Abstract not provided.
Designing an Analog Crossbar based Neuromorphic Accelerator
Abstract not provided.
Solving the performance portability issue with Kokkos
Abstract not provided.
Three-Dimensional DSMC Simulations of the Rayleigh-Taylor Instability
Abstract not provided.
DSMC Simulations of Turbulent Energy Decay in the Taylor-Green Vortex Flow
Abstract not provided.
DSMC Simulations of Taylor-Couette Flow Instabilities
Abstract not provided.
SPARTA Users Group Meeting
Abstract not provided.
Recent algorithmic work in LAMMPS for extending accuracy and time scales for materials modeling
Abstract not provided.
Achieving ideal accuracies in analog neuromorphic computing using periodic carry
Digest of Technical Papers - Symposium on VLSI Technology
Analog resistive memories promise to reduce the energy of neural networks by orders of magnitude. However, the write variability and write nonlinearity of current devices prevent neural networks from training to high accuracy. We present a novel periodic carry method that uses a positional number system to overcome this while maintaining the benefit of parallel analog matrix operations. We demonstrate how noisy, nonlinear TaOx devices that could only train to 80% accuracy on MNIST, can now reach 97% accuracy, only 1% away from an ideal numeric accuracy of 98%. On a file type dataset, the TaOx devices achieve ideal numeric accuracy. In addition, low noise, linear Li1-xCoO2 devices train to ideal numeric accuracies using periodic carry on both datasets.
Spin--lattice simulations with LAMMPS
Abstract not provided.
Spin--lattice simulations with LAMMPS
Abstract not provided.
A Quick Tour of LAMMPS
Abstract not provided.
Welcome and What's New in LAMMPS
Abstract not provided.
LAMMPS Users' Workshop and Symposium
Abstract not provided.
Results 51–75 of 210