Publications

Plimpton, Steven J.

Abstract not provided.

Jayaraj, Jagan J.

Abstract not provided.

Jensen, Richard P.; Mitchell, Scott A.; Heath, Jason; Skryzalin, Jacek S.

Abstract not provided.

Blume-Kohout, Robin J.

Abstract not provided.

Aguilo Valentin, Miguel A.; Beghini, Lauren L.; Clark, Brett W.; Quadros, William R.; Robbins, Joshua R.; Sneed, Brett S.; Voth, Thomas E.

Abstract not provided.

Blume-Kohout, Robin J.

Abstract not provided.

Swiler, Laura P.; Eldred, Michael S.

Abstract not provided.

Bochev, Pavel B.; Ridzal, Denis R.

Abstract not provided.

Proceedings - IEEE International Conference on Cluster Computing, ICCC

Groves, Taylor G.; Grant, Ryan E.; Hemmert, Karl S.; Hammond, Simon D.; Levenhagen, Michael J.; Arnold, Dorian C.

Exascale networks are expected to comprise a significant part of the total monetary cost and 10-20% of the power budget allocated to exascale systems. Yet, our understanding of current and emerging workloads on these networks is limited. Left ignored, this knowledge gap likely will translate into missed opportunities for (1) improved application performance and (2) decreased power and monetary costs in next generation systems. This work targets a detailed understanding and analysis of the performance and utilization of the dragonfly network topology. Using the Structural Simulation Toolkit (SST) and a range of relevant workloads on a dragonfly topology of 110,592 nodes, we examine network design tradeoffs amongst execution time, power, bandwidth, and the number of global links. Our simulations report stalled, active and idle time on a per-port level of the fabric, in order to provide a detailed picture of future networks. The results of this work show potential savings of 3-10% of the exascale power budget and provide valuable insights to researchers looking for new opportunities to improve performance and increase power efficiency of next generation HPC systems.

Sandia journal manuscript; Not yet accepted for publication

Carroll, Malcolm; Lilly, Michael L.; Jacobson, Noah T.

Abstract not provided.

Siefert, Christopher S.; Kramer, Richard M.; Voth, Thomas E.; Bochev, Pavel B.

Abstract not provided.

Debusschere, Bert D.; Jakeman, John D.; Chowdhary, Kamaljit S.; Safta, Cosmin S.; Sargsyan, Khachik S.; Rai, P.R.; Ghanem, R.G.; Knio, O.K.; La Maitre, O.L.; Winokur, J.W.; Li, G.L.; Ghattas, O.G.; Moser, R.M.; Simmons, C.S.; Alexanderian, A.A.; Gattiker, J.G.; Higdon, D.H.; Lawrence, E.L.; Bhat, S.B.; Marzouk, Y.M.; Bigoni, D.B.; Cui, T.C.; Parno, M.P.

Abstract not provided.

Computational and Mathematical Organization Theory

Naugle, Asmeret B.; Russell, Adam R.; Lakkaraju, Kiran L.; Swiler, Laura P.; Verzi, Stephen J.; Romero, Vicente J.

Social systems are uniquely complex and difficult to study, but understanding them is vital to solving the world’s problems. The Ground Truth program developed a new way of testing the research methods that attempt to understand and leverage the Human Domain and its associated complexities. The program developed simulations of social systems as virtual world test beds. Not only were these simulations able to produce data on future states of the system under various circumstances and scenarios, but their causal ground truth was also explicitly known. Research teams studied these virtual worlds, facilitating deep validation of causal inference, prediction, and prescription methods. The Ground Truth program model provides a way to test and validate research methods to an extent previously impossible, and to study the intricacies and interactions of different components of research.

Plimpton, Steven J.

Abstract not provided.

Pundit, Neil D.

Abstract not provided.

Trucano, Timothy G.

Abstract not provided.

Knupp, Patrick K.

Abstract not provided.

Swiler, Laura P.

Abstract not provided.

Thomas, Stephen W.

Abstract not provided.

Eldred, Michael S.

Abstract not provided.

Mitchell, Scott A.

Abstract not provided.

Rogers, David R.

Abstract not provided.

Taylor, Mark A.; Strickland, James H.

Abstract not provided.

Moreland, Kenneth D.

Abstract not provided.

Moreland, Kenneth D.

Abstract not provided.

Willenbring, James M.; Heroux, Michael A.

Abstract not provided.

Clausen, Jonathan C.; Brunini, Victor B.; Forster, Christopher J.; Noble, David R.; Trott, Christian R.; Hammond, Simon D.; Hoemmen, Mark F.; Lin, Paul L.

Abstract not provided.

Hopkins, Matthew M.; Hooper, Russell H.; Crozier, Paul C.; Bettencourt, Matthew T.; Boerner, Jeremiah J.; Musson, Lawrence M.

Abstract not provided.

Hopkins, Matthew M.; Crozier, Paul C.; Barnat, Edward V.; Boerner, Jeremiah J.; Hooper, Russell H.; Bettencourt, Matthew T.; Musson, Lawrence M.

Abstract not provided.

Hopkins, Matthew M.; Crozier, Paul C.; Hooper, Russell H.; Boerner, Jeremiah J.; Musson, Lawrence M.; Bettencourt, Matthew T.

Abstract not provided.

Hopkins, Matthew M.; Crozier, Paul C.; Hooper, Russell H.; Boerner, Jeremiah J.; Musson, Lawrence M.; Bettencourt, Matthew T.

Abstract not provided.

Stewart, James R.

Abstract not provided.

Landahl, Andrew J.

Abstract not provided.

Acer, Seher A.; Boman, Erik G.; Aykanat, Cevdet A.

Abstract not provided.

Tran, Anh; Tran, Hoang T.

Abstract not provided.

Boman, Erik G.; Devine, Karen D.; Rajamanickam, Sivasankaran R.

Abstract not provided.

Moore, Stan G.; Moore, Christopher H.; Boerner, Jeremiah J.

Abstract not provided.

Bertagna, Luca B.

Abstract not provided.

Plimpton, Steven J.

Abstract not provided.

Kalinina, Elena A.; Ammerman, Douglas J.; Grey, Carissa A.; Arviso, Michael A.; Wright, Catherine W.; Lujan, Lucas A.; Flores, Gregg J.; Saltzstein, Sylvia J.

The data from the multi-modal transportation test conducted in 2017 demonstrated that the inputs from the shock events during all transport modes (truck, rail, and ship) were amplified from the cask to the spent commercial nuclear fuel surrogate assemblies. These data do not support common assumption that the cask content experiences the same accelerations as the cask itself. This was one of the motivations for conducting 30 cm drop tests. The goal of the 30 cm drop test is to measure accelerations and strains on the surrogate spent nuclear fuel assembly and to determine whether the fuel rods can maintain their integrity inside a transportation cask when dropped from a height of 30 cm. The 30 cm drop is the remaining NRC normal conditions of transportation regulatory requirement (10 CFR 71.71) for which there are no data on the actual surrogate fuel. Because the full-scale cask and impact limiters were not available (and their cost was prohibitive), it was proposed to achieve this goal by conducting three separate tests. This report describes the first two tests — the 30 cm drop test of the 1/3 scale cask (conducted in December 2018) and the 30 cm drop of the full-scale dummy assembly (conducted in June 2019). The dummy assembly represents the mass of a real spent nuclear fuel assembly. The third test (to be conducted in the spring of 2020) will be the 30 cm drop of the full-scale surrogate assembly. The surrogate assembly represents a real full-scale assembly in physical, material, and mechanical characteristics, as well as in mass.

Plimpton, Steven J.

Abstract not provided.

Ivanoff, Thomas I.; Madison, Jonathan D.; Koepke, Joshua R.; Jared, Bradley H.; Mitchell, John A.; Swiler, Laura P.

Abstract not provided.

Ivanoff, Thomas I.; Madison, Jonathan D.; Koepke, Joshua R.; Jared, Bradley H.; Mitchell, John A.; Swiler, Laura P.

Abstract not provided.

DeBenedictis, Erik

Abstract not provided.

Haaland, David M.; Sinclair, Michael B.; Jones, Howland D.; Timlin, Jerilyn A.; Bachand, George B.; Sasaki, Darryl Y.; Davidson, George S.; Van Benthem, Mark V.

A novel hyperspectral fluorescence microscope for high-resolution 3D optical sectioning of cells and other structures has been designed, constructed, and used to investigate a number of different problems. We have significantly extended new multivariate curve resolution (MCR) data analysis methods to deconvolve the hyperspectral image data and to rapidly extract quantitative 3D concentration distribution maps of all emitting species. The imaging system has many advantages over current confocal imaging systems including simultaneous monitoring of numerous highly overlapped fluorophores, immunity to autofluorescence or impurity fluorescence, enhanced sensitivity, and dramatically improved accuracy, reliability, and dynamic range. Efficient data compression in the spectral dimension has allowed personal computers to perform quantitative analysis of hyperspectral images of large size without loss of image quality. We have also developed and tested software to perform analysis of time resolved hyperspectral images using trilinear multivariate analysis methods. The new imaging system is an enabling technology for numerous applications including (1) 3D composition mapping analysis of multicomponent processes occurring during host-pathogen interactions, (2) monitoring microfluidic processes, (3) imaging of molecular motors and (4) understanding photosynthetic processes in wild type and mutant Synechocystis cyanobacteria.

Ivanoff, Thomas I.; Madison, Jonathan D.; Koepke, Joshua R.; Swaller, Erich S.; Jared, Bradley H.; Mitchell, John A.; Swiler, Laura P.

Abstract not provided.

Hopkins, Matthew M.; Boerner, Jeremiah J.; Barnat, Edward V.; Crozier, Paul C.; Bettencourt, Matthew T.; Musson, Lawrence M.; Hooper, Russell H.; Moore, Christopher H.

Abstract not provided.

Plimpton, Steven J.; Lane, James M.; Lechman, Jeremy B.

Abstract not provided.

Trott, Christian R.; Shipman, Galen S.; Lopez, Graham L.

Abstract not provided.

Davis, Jean-Paul D.; Lane, James M.; Thompson, Aidan P.; Drake, Richard R.; Weirs, Vincent G.; Flicker, Dawn G.; Robbins, Joshua R.; Lemke, Raymond W.; Martin, Matthew; Alexander, Charles S.; Haill, Thomas A.; Ao, Tommy A.; Dolan, Daniel H.

Abstract not provided.