A. G. Ovcharenko scite author profile

The NEURON simulator has been developed over the past three decades and is widely used by neuroscientists to model the electrical activity of neuronal networks. Large network simulation projects using NEURON have supercomputer allocations that individually measure in the millions of core hours. Supercomputer centers are transitioning to next generation architectures and the work accomplished per core hour for these simulations could be improved by an order of magnitude if NEURON was able to better utilize those new hardware capabilities. In order to adapt NEURON to evolving computer architectures, the compute engine of the NEURON simulator has been extracted and has been optimized as a library called CoreNEURON. This paper presents the design, implementation, and optimizations of CoreNEURON. We describe how CoreNEURON can be used as a library with NEURON and then compare performance of different network models on multiple architectures including IBM BlueGene/Q, Intel Skylake, Intel MIC and NVIDIA GPU. We show how CoreNEURON can simulate existing NEURON network models with 4–7x less memory usage and 2–7x less execution time while maintaining binary result compatibility with NEURON.

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Leveraging a Cluster-Booster Architecture for Brain-Scale Simulations

Kumbhar

Hines

Ovcharenko

et al. 2016

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Parallel Adaptive Boundary Layer Meshing for CFD Analysis

Ovcharenko

Chitale

Sahni

et al. 2013

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Summary. This paper describes a parallel procedure for anisotropic mesh adaptation with boundary layers for use in scalable CFD simulations. The parallel mesh adaptation algorithm operates with local mesh modification operations developed for both unstructured and boundary layer parts of the mesh. The adaptive approach maintains layered elements near the viscous walls and accounts for the mesh modification operations that are carried out in parallel on a distributed mesh. In the process mesh relationships and approximations with respect to curved complex 3D geometries of interest are properly maintained. The parallel mesh adaptation procedures are applied to two problems: a heat transfer manifold and a scramjet engine.

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26th Annual Computational Neuroscience Meeting (CNS*2017): Part 3

Newton¹,

Seidenstein²,

McDougal³

et al. 2017

BMC Neurosci

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A. G. Ovcharenko

Reconstruction and Simulation of Neocortical Microcircuitry

CoreNEURON : An Optimized Compute Engine for the NEURON Simulator

Leveraging a Cluster-Booster Architecture for Brain-Scale Simulations

Parallel Adaptive Boundary Layer Meshing for CFD Analysis

26th Annual Computational Neuroscience Meeting (CNS*2017): Part 3

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