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2020 – today
- 2024
[i9]Torsten Hoefler, Marcin Copik
, Pete Beckman, Andrew Jones, Ian T. Foster, Manish Parashar, Daniel A. Reed, Matthias Troyer, Thomas C. Schulthess, Dan Ernst, Jack J. Dongarra:
XaaS: Acceleration as a Service to Enable Productive High-Performance Cloud Computing. CoRR abs/2401.04552 (2024)- [i8]Torsten Hoefler, Alexandru Calotoiu, Anurag Dipankar, Thomas C. Schulthess, Xavier Lapillonne, Oliver Fuhrer:
Towards Specialized Supercomputers for Climate Sciences: Computational Requirements of the Icosahedral Nonhydrostatic Weather and Climate Model. CoRR abs/2405.13043 (2024) - [i7]Luigi Fusco, Mikhail Khalilov, Marcin Chrapek, Giridhar Chukkapalli, Thomas C. Schulthess, Torsten Hoefler:
Understanding Data Movement in Tightly Coupled Heterogeneous Systems: A Case Study with the Grace Hopper Superchip. CoRR abs/2408.11556 (2024) - 2023
- [j15]Torsten Hoefler, Bjorn Stevens, Andreas F. Prein, Johanna Baehr, Thomas C. Schulthess, Thomas F. Stocker, John A. Taylor, Daniel Klocke, Pekka Manninen, Piers M. Forster, Tobias Kölling, Nicolas Gruber, Hartwig Anzt, Claudia Frauen, Florian Ziemen, Milan Klöwer, Karthik Kashinath, Christoph M. Schär, Oliver Fuhrer, Bryan N. Lawrence:
Earth Virtualization Engines: A Technical Perspective. Comput. Sci. Eng. 25(3): 50-59 (2023) - [j14]Sadaf R. Alam, Miguel Gila, Mark Klein, Maxime Martinasso, Thomas C. Schulthess:
Versatile software-defined HPC and cloud clusters on Alps supercomputer for diverse workflows. Int. J. High Perform. Comput. Appl. 37(3-4): 288-305 (2023) - [c28]Roman Gruber, Anton Kozhevnikov, Marina Marinkovic, Thomas C. Schulthess, Raffaele Solcà:
Towards Lattice QCD+QED Simulations on GPUs. PASC 2023: 7:1-7:8 - [i6]Torsten Hoefler, Bjorn Stevens, Andreas F. Prein, Johanna Baehr, Thomas C. Schulthess, Thomas F. Stocker, John A. Taylor, Daniel Klocke, Pekka Manninen, Piers M. Forster, Tobias Kölling, Nicolas Gruber, Hartwig Anzt, Claudia Frauen, Florian Ziemen, Milan Klöwer, Karthik Kashinath, Christoph M. Schär, Oliver Fuhrer, Bryan N. Lawrence:
Earth Virtualization Engines - A Technical Perspective. CoRR abs/2309.09002 (2023) - [i5]Enrique G. Paredes, Linus Groner, Stefano Ubbiali, Hannes Vogt, Alberto Madonna, Kean Mariotti, Felipe A. Cruz, Lucas Benedicic, Mauro Bianco, Joost VandeVondele, Thomas C. Schulthess:
GT4Py: High Performance Stencils for Weather and Climate Applications using Python. CoRR abs/2311.08322 (2023) - 2022
- [j13]Long Zhang, Anton Kozhevnikov, Thomas C. Schulthess, Hai-Ping Cheng, Samuel B. Trickey:
Performance Enhancement of APW+lo Calculations by Simplest Separation of Concerns. Comput. 10(3): 43 (2022) - [c27]Tal Ben-Nun, Linus Groner, Florian Deconinck, Tobias Wicky, Eddie Davis, Johann Dahm, Oliver Elbert, Rhea George, Jeremy McGibbon, Lukas Trümper, Elynn Wu, Oliver Fuhrer, Thomas C. Schulthess, Torsten Hoefler:
Productive Performance Engineering for Weather and Climate Modeling with Python. SC 2022: 73:1-73:14 - [i4]Tal Ben-Nun, Linus Groner, Florian Deconinck, Tobias Wicky, Eddie Davis, Johann Dahm, Oliver Elbert, Rhea George, Jeremy McGibbon, Lukas Trümper, Elynn Wu, Oliver Fuhrer, Thomas C. Schulthess, Torsten Hoefler:
Productive Performance Engineering for Weather and Climate Modeling with Python. CoRR abs/2205.04148 (2022) - 2021
- [j12]Peter Bauer, Peter D. Düben, Torsten Hoefler, Tiago Quintino, Thomas C. Schulthess, Nils P. Wedi:
The digital revolution of Earth-system science. Nat. Comput. Sci. 1(2): 104-113 (2021) - [j11]Núria López, Luigi Del Debbio, Marc Baaden, Matej Praprotnik, Laura Grigori, Catarina Simões, Serge Bogaerts, Florian Berberich, Thomas Lippert, Janne Ignatius, Philippe Lavocat, Oriol Pineda, Maria Grazia Giuffreda, Sergi Girona, Dieter Kranzlmüller, Michael M. Resch, Gabriella Scipione, Thomas C. Schulthess:
Lessons learned from urgent computing in Europe: Tackling the COVID-19 pandemic. Proc. Natl. Acad. Sci. USA 118(46): e2024891118 (2021) - [j10]Anton Afanasyev, Mauro Bianco, Lukas Mosimann, Carlos Osuna, Felix Thaler, Hannes Vogt, Oliver Fuhrer, Joost VandeVondele, Thomas C. Schulthess:
GridTools: A framework for portable weather and climate applications. SoftwareX 15: 100707 (2021) - 2020
- [j9]Urs R. Hähner, Gonzalo Alvarez, Thomas A. Maier, Raffaele Solcà, Peter W. J. Staar, Michael S. Summers, Thomas C. Schulthess:
DCA++: A software framework to solve correlated electron problems with modern quantum cluster methods. Comput. Phys. Commun. 246 (2020) - [c26]Sadaf R. Alam, Javier Bartolome, Sanzio Bassini, Michele Carpenè, Mirko Cestari, Frederic Combeau, Sergi Girona, Stefano Gorini, Giuseppe Fiameni, Björn Hagemeier, Thorsten Hater, Andreas Herten, Nikoleta Kiapidou, Wouter Klijn, Dorian Krause, Jacques-Charles Lafoucriere, Cerlane Leong, Thomas Leibovici, Thomas Lippert, Colin McMurtrie, Pavel Mezentsev, Anne Nahm, Boris Orth, Dirk Pleiter, Thomas C. Schulthess, Benedikt von St. Vieth, Debora Testi, Gilles Wiber:
Archival Data Repository Services to Enable HPC and Cloud Workflows in a Federated Research e-Infrastructure. SuperCompCloud@SC 2020: 39-44 - [c25]Sadaf R. Alam, Mark Klein, Mauro Bianco, Roberto Aielli, Xavier Lapillonne, Andre Walser, Thomas C. Schulthess:
Software Defined Infrastructure for Operational Numerical Weather Prediction. SMC 2020: 303-317
2010 – 2019
- 2019
- [j8]Thomas C. Schulthess, Peter Bauer, Nils Wedi, Oliver Fuhrer, Torsten Hoefler, Christoph M. Schär:
Reflecting on the Goal and Baseline for Exascale Computing: A Roadmap Based on Weather and Climate Simulations. Comput. Sci. Eng. 21(1): 30-41 (2019) - [c24]Giovanni Balduzzi, Arghya Chatterjee, Ying Wai Li, Peter W. Doak, Urs R. Hähner, Eduardo F. D'Azevedo, Thomas A. Maier, Thomas C. Schulthess:
Accelerating DCA++ (Dynamical Cluster Approximation) Scientific Application on the Summit Supercomputer. PACT 2019: 433-444 - [c23]Sadaf R. Alam, Javier Bartolome, Sanzio Bassini, Michele Carpenè, Mirko Cestari, Frederic Combeau, Sergi Girona, Stefano Gorini, Giuseppe Fiameni, Björn Hagemeier, Andreas Herten, Nikoleta Kiapidou, Wouter Klijn, Dorian Krause, Jacques-Charles Lafoucriere, Cerlane Leong, Thomas Leibovici, Thomas Lippert, Colin McMurtrie, Pavel Mezentsev, Anne Nahm, Boris Orth, Dirk Pleiter, Thomas C. Schulthess, Benedikt von St. Vieth, Debora Testi, Gilles Wiber:
Fenix: Distributed e-Infrastructure Services for EBRAINS. BrainComp 2019: 81-89 - [c22]Salvatore Di Girolamo, Pirmin Schmid, Thomas C. Schulthess, Torsten Hoefler:
SimFS: A Simulation Data Virtualizing File System Interface. IPDPS 2019: 621-630 - [c21]Felix Thaler, Stefan Moosbrugger, Carlos Osuna, Mauro Bianco, Hannes Vogt, Anton Afanasyev, Lukas Mosimann, Oliver Fuhrer, Thomas C. Schulthess, Torsten Hoefler:
Porting the COSMO Weather Model to Manycore CPUs. PASC 2019: 13:1-13:11 - [i3]Salvatore Di Girolamo, Pirmin Schmid, Thomas C. Schulthess, Torsten Hoefler:
SimFS: A Simulation Data Virtualizing File System Interface. CoRR abs/1902.03154 (2019) - 2018
- [j7]Mark Asch, Terry Moore, Rosa M. Badia, Micah Beck, Peter H. Beckman, T. Bidot, François Bodin, Franck Cappello, Alok N. Choudhary, Bronis R. de Supinski, Ewa Deelman, Jack J. Dongarra, Anshu Dubey, Geoffrey C. Fox, H. Fu, Sergi Girona, William Gropp, Michael A. Heroux, Yutaka Ishikawa, Katarzyna Keahey, David E. Keyes, Bill Kramer, J.-F. Lavignon, Y. Lu, Satoshi Matsuoka, Bernd Mohr, Daniel A. Reed, S. Requena, Joel H. Saltz, Thomas C. Schulthess, Rick L. Stevens, D. Martin Swany, Alexander S. Szalay, William M. Tang, G. Varoquaux, Jean-Pierre Vilotte, Robert W. Wisniewski, Z. Xu, Igor Zacharov:
Big data and extreme-scale computing. Int. J. High Perform. Comput. Appl. 32(4): 435-479 (2018) - [c20]Maxime Martinasso, Miguel Gila, Mauro Bianco, Sadaf R. Alam, Colin McMurtrie, Thomas C. Schulthess:
RM-replay: a high-fidelity tuning, optimization and exploration tool for resource management. SC 2018: 25:1-25:13 - [c19]Tsuyoshi Ichimura, Kohei Fujita, Takuma Yamaguchi, Akira Naruse, Jack C. Wells, Thomas C. Schulthess, Tjerk P. Straatsma, Christopher Zimmer, Maxime Martinasso, Kengo Nakajima, Muneo Hori, Lalith Maddegedara:
A fast scalable implicit solver for nonlinear time-evolution earthquake city problem on low-ordered unstructured finite elements with artificial intelligence and transprecision computing. SC 2018: 49:1-49:11 - 2017
- [c18]Andrea Arteaga, Oliver Fuhrer, Torsten Hoefler, Thomas C. Schulthess:
Model-Driven Choice of Numerical Methods for the Solution of the Linear Advection Equation. ICCS 2017: 1542-1551 - 2016
- [c17]Maxime Martinasso, Grzegorz Kwasniewski, Sadaf R. Alam, Thomas C. Schulthess, Torsten Hoefler:
A PCIe congestion-aware performance model for densely populated accelerator servers. SC 2016: 739-749 - 2015
- [c16]Carlos Osuna, Oliver Fuhrer, Tobias Gysi, Thomas C. Schulthess:
Porting the COSMO dynamical core to heterogeneous platforms using STELLA Library. PARCO 2015: 637-646 - [c15]Raffaele Solcà, Anton Kozhevnikov, Azzam Haidar, Stanimire Tomov, Jack J. Dongarra, Thomas C. Schulthess:
Efficient implementation of quantum materials simulations on distributed CPU-GPU systems. SC 2015: 10:1-10:12 - [c14]Tobias Gysi, Carlos Osuna, Oliver Fuhrer, Mauro Bianco, Thomas C. Schulthess:
STELLA: a domain-specific tool for structured grid methods in weather and climate models. SC 2015: 41:1-41:12 - 2014
- [j6]Ichitaro Yamazaki, Tingxing Dong, Raffaele Solcà, Stanimire Tomov, Jack J. Dongarra, Thomas C. Schulthess:
Tridiagonalization of a dense symmetric matrix on multiple GPUs and its application to symmetric eigenvalue problems. Concurr. Comput. Pract. Exp. 26(16): 2652-2666 (2014) - [j5]Azzam Haidar, Stanimire Tomov, Jack J. Dongarra, Raffaele Solcà, Thomas C. Schulthess:
A novel hybrid CPU-GPU generalized eigensolver for electronic structure calculations based on fine-grained memory aware tasks. Int. J. High Perform. Comput. Appl. 28(2): 196-209 (2014) - [j4]Oliver Fuhrer, Carlos Osuna, Xavier Lapillonne, Tobias Gysi, Ben Cumming, Mauro Bianco, Andrea Arteaga, Thomas C. Schulthess:
Towards a performance portable, architecture agnostic implementation strategy for weather and climate models. Supercomput. Front. Innov. 1(1): 45-62 (2014) - [c13]Ben Cumming, Gilles Fourestey, Oliver Fuhrer, Tobias Gysi, Massimiliano Fatica, Thomas C. Schulthess:
Application Centric Energy-Efficiency Study of Distributed Multi-Core and Hybrid CPU-GPU Systems. SC 2014: 819-829 - [i2]Gilles Fourestey, Ben Cumming, Ladina Gilly, Thomas C. Schulthess:
First Experiences With Validating and Using the Cray Power Management Database Tool. CoRR abs/1408.2657 (2014) - 2013
- [j3]Sadaf R. Alam, Constantine Bekas, Hans Boettiger, Alessandro Curioni, Gilles Fourestey, Willi Homberg, Michael Knobloch, Teodoro Laino, Thilo Maurer, Bernd Mohr, Dirk Pleiter, Arwed Schiller, Thomas C. Schulthess, Valéry Weber:
Early experiences with scientific applications on the IBM Blue Gene/Q supercomputer. IBM J. Res. Dev. 57(1/2): 14 (2013) - [c12]Turlough P. Downes, Sabine Roller, Ari P. Seitsonen, Sophie Valcke, David E. Keyes, Marie-Christine Sawley, Thomas C. Schulthess, John Shalf:
Topic 14+16: High-Performance and Scientific Applications and Extreme-Scale Computing - (Introduction). Euro-Par 2013: 737-738 - [c11]Peter W. J. Staar, Thomas A. Maier, Michael S. Summers, Gilles Fourestey, Raffaele Solcà, Thomas C. Schulthess:
Taking a quantum leap in time to solution for simulations of high-Tc superconductors. SC 2013: 1:1-1:11 - [c10]Azzam Haidar, Raffaele Solcà, Mark Gates, Stanimire Tomov, Thomas C. Schulthess, Jack J. Dongarra:
Leading Edge Hybrid Multi-GPU Algorithms for Generalized Eigenproblems in Electronic Structure Calculations. ISC 2013: 67-80 - 2012
- [j2]Adrian Tineo, Sadaf R. Alam, Thomas C. Schulthess:
Towards autotuning by alternating communication methods. SIGMETRICS Perform. Evaluation Rev. 40(2): 80-85 (2012) - [c9]Raffaele Solcà, Azzam Haidar, Stanimire Tomov, Thomas C. Schulthess, Jack J. Dongarra:
Abstract: A Novel Hybrid CPU-GPU Generalized Eigensolver for Electronic Structure Calculations Based on Fine Grained Memory Aware Tasks. SC Companion 2012: 1338-1339 - [c8]Raffaele Solcà, Azzam Haidar, Stanimire Tomov, Thomas C. Schulthess, Jack J. Dongarra:
Poster: A Novel Hybrid CPU-GPU Generalized Eigensolver for Electronic Structure Calculations Based on Fine Grained Memory Aware Tasks. SC Companion 2012: 1340 - [i1]Raffaele Solcà, Thomas C. Schulthess, Azzam Haidar, Stanimire Tomov, Ichitaro Yamazaki, Jack J. Dongarra:
A hybrid Hermitian general eigenvalue solver. CoRR abs/1207.1773 (2012) - 2010
- [c7]Xiuping Tao, Andrew J. Bordner, Thomas C. Schulthess, Andrey A. Gorin:
Kernelling Method for Identifying Near-Native Protein Decoy Structures. BIOCOMP 2010: 225-228 - [c6]Anton Kozhevnikov, Adolfo G. Eguiluz, Thomas C. Schulthess:
Toward First Principles Electronic Structure Simulations of Excited States and Strong Correlations in Nano- and Materials Science. SC 2010: 1-10
2000 – 2009
- 2009
- [j1]Jeremy S. Meredith, Gonzalo Alvarez, Thomas A. Maier, Thomas C. Schulthess, Jeffrey S. Vetter:
Accuracy and performance of graphics processors: A Quantum Monte Carlo application case study. Parallel Comput. 35(3): 151-163 (2009) - [c5]Markus Eisenbach, C.-G. Zhou, Donald M. C. Nicholson, G. Brown, Jeffrey M. Larkin, Thomas C. Schulthess:
A scalable method for ab initio computation of free energies in nanoscale systems. SC 2009 - 2008
- [c4]Gonzalo Alvarez, Michael S. Summers, Don E. Maxwell, Markus Eisenbach, Jeremy S. Meredith, Jeffrey M. Larkin, John M. Levesque, Thomas A. Maier, Paul R. C. Kent, Eduardo F. D'Azevedo, Thomas C. Schulthess:
New algorithm to enable 400+ TFlop/s sustained performance in simulations of disorder effects in high-Tc superconductors. SC 2008: 61 - 2006
- [c3]Thomas C. Schulthess:
Materials and nano-science - Toward material-specific simulations of high temperature superconductivity. SC 2006: 63 - 2003
- [c2]Andrew Canning, B. Ujfalussy, Thomas C. Schulthess, Xiaoguang Zhang, William A. Shelton, Donald M. C. Nicholson, G. Malcolm Stocks, Yang Wang, T. Dirks:
Parallel Multi-Teraflops Studies of the Magnetic Structure of FeMn Alloys. IPDPS 2003: 256 - 2001
- [c1]Andrew Canning, B. Ujfalussy, Thomas C. Schulthess, Xiaoguang Zhang, William A. Shelton, Donald M. C. Nicholson, G. Malcolm Stocks, Yang Wang, T. Dirks:
Multi-teraflops spin dynamics studies of the magnetic structure of FeMn/Co interfaces. SC 2001: 44
Coauthor Index
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last updated on 2024-10-07 21:17 CEST by the dblp team
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