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Erik W. Draeger
2020 – today
- 2024
- [j14]Erik W. Draeger, Andrew R. Siegel, Steven Gottlieb:
The Scientific Impact of the Exascale Computing Project. Comput. Sci. Eng. 26(2): 4-6 (2024) - [j13]Cyrus Tanade, Nusrat Sadia Khan, Emily Rakestraw, William Ladd, Erik W. Draeger, Amanda Randles:
Establishing the longitudinal hemodynamic mapping framework for wearable-driven coronary digital twins. npj Digit. Medicine 7(1) (2024) - [c24]Aristotle X. Martin, Geng Liu, Bálint Joó, Runxin Wu, Mohammed Shihab Kabir, Erik W. Draeger, Amanda Randles:
Designing a GPU-Accelerated Communication Layer for Efficient Fluid-Structure Interaction Computations on Heterogeneous Systems. SC 2024: 93 - 2023
- [j12]Erik W. Draeger, Andrew R. Siegel:
Exascale Was Not Inevitable; Neither Is What Comes Next. Comput. Sci. Eng. 25(3): 79-83 (2023) - [j11]Sayan Roychowdhury, Erik W. Draeger, Amanda Randles:
Establishing metrics to quantify spatial similarity in spherical and red blood cell distributions. J. Comput. Sci. 71: 102060 (2023) - [c23]William Ladd, Christopher Jensen, Madhurima Vardhan, Jeff Ames, Jeff R. Hammond, Erik W. Draeger, Amanda Randles:
Optimizing Cloud Computing Resource Usage for Hemodynamic Simulation. IPDPS 2023: 568-578 - [c22]Ayman Z. Yousef, Erik W. Draeger, Amanda Randles:
Low-Cost Post Hoc Reconstruction of HPC Simulations at Full Resolution. LDAV 2023: 17-21 - [c21]Sayan Roychowdhury, Samreen T. Mahmud, Aristotle X. Martin, Peter Balogh, Daniel F. Puleri, John Gounley, Erik W. Draeger, Amanda Randles:
Enhancing Adaptive Physics Refinement Simulations Through the Addition of Realistic Red Blood Cell Counts. SC 2023: 41:1-41:13 - [c20]Cyrus Tanade, Emily Rakestraw, William Ladd, Erik W. Draeger, Amanda Randles:
Cloud Computing to Enable Wearable-Driven Longitudinal Hemodynamic Maps. SC 2023: 82:1-82:14 - [c19]John K. Holmen, Verónica G. Vergara Larrea, Erik W. Draeger, Eric T. Phipps, Philip J. Smith, Martin Berzins, Sean T. Smith, Jeremy N. Thornock, Suzanne Parete-Koon:
Strengthening the US Department of Energy's Recruitment Pipeline: The DOE/NNSA Predictive Science Academic Alliance Program (PSAAP) Experience. PEARC 2023: 137-144 - 2022
- [j10]Thomas M. Evans, Andrew R. Siegel, Erik W. Draeger, Jack Deslippe, Marianne M. Francois, Timothy C. Germann, William E. Hart, Daniel F. Martin:
A survey of software implementations used by application codes in the Exascale Computing Project. Int. J. High Perform. Comput. Appl. 36(1): 5-12 (2022) - [j9]John Gounley, Madhurima Vardhan, Erik W. Draeger, Pedro Valero-Lara, Shirley V. Moore, Amanda Randles:
Propagation Pattern for Moment Representation of the Lattice Boltzmann Method. IEEE Trans. Parallel Distributed Syst. 33(3): 642-653 (2022) - [c18]Daniel F. Puleri, Sayan Roychowdhury, Peter Balogh, John Gounley, Erik W. Draeger, Jeff Ames, Adebayo Adebiyi, Simbarashe Chidyagwai, Benjamín Hernández, Seyong Lee, Shirley V. Moore, Jeffrey S. Vetter, Amanda Randles:
High Performance Adaptive Physics Refinement to Enable Large-Scale Tracking of Cancer Cell Trajectory. CLUSTER 2022: 230-242 - [c17]Sayan Roychowdhury, Erik W. Draeger, Amanda Randles:
Establishing Metrics to Quantify Underlying Structure in Vascular Red Blood Cell Distributions. ICCS (1) 2022: 89-102 - 2021
- [j8]Anshu Dubey, Lois Curfman McInnes, Rajeev Thakur, Erik W. Draeger, Thomas M. Evans, Timothy C. Germann, William E. Hart:
Performance Portability in the Exascale Computing Project: Exploration Through a Panel Series. Comput. Sci. Eng. 23(5): 46-54 (2021) - [j7]Lois Curfman McInnes, Michael A. Heroux, Erik W. Draeger, Andrew R. Siegel, Susan Coghlan, Katie Antypas:
How community software ecosystems can unlock the potential of exascale computing. Nat. Comput. Sci. 1(2): 92-94 (2021) - 2020
- [j6]Jeff Ames, Daniel F. Puleri, Peter Balogh, John Gounley, Erik W. Draeger, Amanda Randles:
Multi-GPU immersed boundary method hemodynamics simulations. J. Comput. Sci. 44: 101153 (2020)
2010 – 2019
- 2019
- [c16]Gregory Herschlag, John Gounley, Sayan Roychowdhury, Erik W. Draeger, Amanda Randles:
Multi-physics simulations of particle tracking in arterial geometries with a scalable moving window algorithm. CLUSTER 2019: 1-11 - [c15]John Gounley, Erik W. Draeger, Amanda Randles:
Immersed Boundary Method Halo Exchange in a Hemodynamics Application. ICCS (1) 2019: 441-455 - [c14]Jeff Ames, Silvio Rizzi, Joseph A. Insley, Saumil Patel, Benjamín Hernández, Erik W. Draeger, Amanda Randles:
Low-Overhead In Situ Visualization Using Halo Replay. LDAV 2019: 16-26 - [c13]Madhurima Vardhan, John Gounley, Luiz Hegele, Erik W. Draeger, Amanda Randles:
Moment representation in the lattice Boltzmann method on massively parallel hardware. SC 2019: 34:1-34:21 - 2017
- [j5]Erik W. Draeger, Xavier Andrade, John A. Gunnels, Abhinav Bhatele, Andre Schleife, Alfredo A. Correa:
Massively parallel first-principles simulation of electron dynamics in materials. J. Parallel Distributed Comput. 106: 205-214 (2017) - [c12]John Gounley, Erik W. Draeger, Amanda Randles:
Numerical simulation of a compound capsule in a constricted microchannel. ICCS 2017: 175-184 - 2016
- [c11]Harsh Bhatia, Attila Gyulassy, Valerio Pascucci, Martina Bremer, Mitchell T. Ong, Vincenzo Lordi, Erik W. Draeger, John E. Pask, Peer-Timo Bremer:
Interactive exploration of atomic trajectories through relative-angle distribution and associated uncertainties. PacificVis 2016: 120-127 - [c10]Erik W. Draeger, Xavier Andrade, John A. Gunnels, Abhinav Bhatele, Andre Schleife, Alfredo A. Correa:
Massively Parallel First-Principles Simulation of Electron Dynamics in Materials. IPDPS 2016: 832-841 - [c9]Ian Karlin, Tom Scogland, Arpith C. Jacob, Samuel F. Antão, Gheorghe-Teodor Bercea, Carlo Bertolli, Bronis R. de Supinski, Erik W. Draeger, Alexandre E. Eichenberger, Jim Glosli, Holger Jones, Adam Kunen, David Poliakoff, David F. Richards:
Early Experiences Porting Three Applications to OpenMP 4.5. IWOMP 2016: 281-292 - [c8]Jean-Luc Fattebert, Daniel Osei-Kuffuor, Erik W. Draeger, Tadashi Ogitsu, William D. Krauss:
Modeling dilute solutions using first-principles molecular dynamics: computing more than a million atoms with over a million cores. SC 2016: 12-22 - 2015
- [j4]Amanda Randles, Erik W. Draeger, Peter E. Bailey:
Massively parallel simulations of hemodynamics in the primary large arteries of the human vasculature. J. Comput. Sci. 9: 70-75 (2015) - [c7]Amanda Randles, Erik W. Draeger, Tomas Oppelstrup, Liam Krauss, John A. Gunnels:
Massively parallel models of the human circulatory system. SC 2015: 1:1-1:11 - 2014
- [j3]Andre Schleife, Erik W. Draeger, Victor M. Anisimov, Alfredo A. Correa, Yosuke Kanai:
Quantum Dynamics Simulation of Electrons in Materials on High-Performance Computers. Comput. Sci. Eng. 16(5): 54-60 (2014) - [c6]Amanda Randles, Erik W. Draeger, Franziska Michor:
Analysis of Pressure Gradient Across Aortic Stenosis with Massively Parallel Computational Simulation. CinC 2014: 217-220 - 2013
- [j2]Brian Carnes, Bor Chan, Erik W. Draeger, Jean-Luc Fattebert, Larry Fried, James N. Glosli, William D. Krauss, Steve H. Langer, Rose McCallen, Arthur A. Mirin, Fady Najjar, Albert L. Nichols, Tomas Oppelstrup, James A. Rathkopf, David F. Richards, Frederick H. Streitz, Pavlos Vranas, John Jeremy Rice, John A. Gunnels, Viatcheslav Gurev, Changhoan Kim, John Magerlein, Matthias Reumann, Hui-Fang Wen:
Science at LLNL with IBM Blue Gene/Q. IBM J. Res. Dev. 57(1/2): 11 (2013) - 2012
- [c5]Arthur A. Mirin, David F. Richards, James N. Glosli, Erik W. Draeger, Bor Chan, Jean-Luc Fattebert, William D. Krauss, Tomas Oppelstrup, John Jeremy Rice, John A. Gunnels, Viatcheslav Gurev, Changhoan Kim, John Magerlein, Matthias Reumann, Hui-Fang Wen:
Toward real-time modeling of human heart ventricles at cellular resolution: simulation of drug-induced arrhythmias. SC 2012: 2 - [c4]Abhinav Bhatele, Todd Gamblin, Steve H. Langer, Peer-Timo Bremer, Erik W. Draeger, Bernd Hamann, Katherine E. Isaacs, Aaditya G. Landge, Joshua A. Levine, Valerio Pascucci, Martin Schulz, Charles H. Still:
Mapping applications with collectives over sub-communicators on torus networks. SC 2012: 97
2000 – 2009
- 2009
- [c3]David F. Richards, James N. Glosli, Bor Chan, Milo R. Dorr, Erik W. Draeger, Jean-Luc Fattebert, William D. Krauss, Thomas E. Spelce, Frederick H. Streitz, Michael P. Surh, John A. Gunnels:
Beyond homogeneous decomposition: scaling long-range forces on Massively Parallel Systems. SC 2009 - 2008
- [j1]Bronis R. de Supinski, Martin Schulz, Vasily V. Bulatov, William H. Cabot, Bor Chan, Andrew W. Cook, Erik W. Draeger, James N. Glosli, Jeffrey A. Greenough, Keith W. Henderson, Alison Kubota, Steve Louis, Brian J. Miller, Mehul V. Patel, Thomas E. Spelce, Frederick H. Streitz, Peter L. Williams, Robert K. Yates, Andy Yoo, George Almási, Gyan Bhanot, Alan Gara, John A. Gunnels, Manish Gupta, José E. Moreira, James C. Sexton, Robert Walkup, Charles Archer, François Gygi, Timothy C. Germann, Kai Kadau, Peter S. Lomdahl, Charles A. Rendleman, Michael L. Welcome, William McLendon, Bruce Hendrickson, Franz Franchetti, Stefan Kral, Juergen Lorenz, Christoph W. Überhuber, Edmond Chow, Ümit V. Çatalyürek:
BlueGene/L applications: Parallelism On a Massive Scale. Int. J. High Perform. Comput. Appl. 22(1): 33-51 (2008) - 2006
- [c2]François Gygi, Erik W. Draeger, Martin Schulz, Bronis R. de Supinski, John A. Gunnels, Vernon Austel, James C. Sexton, Franz Franchetti, Stefan Kral, Christoph W. Ueberhuber, Juergen Lorenz:
Gordon Bell finalists I - Large-scale electronic structure calculations of high-Z metals on the BlueGene/L platform. SC 2006: 45 - 2005
- [c1]François Gygi, Robert K. Yates, Juergen Lorenz, Erik W. Draeger, Franz Franchetti, Christoph W. Ueberhuber, Bronis R. de Supinski, Stefan Kral, John A. Gunnels, James C. Sexton:
Large-Scale First-Principles Molecular Dynamics simulations on the BlueGene/L Platform using the Qbox code. SC 2005: 24
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