Texas Advanced Computing Center
The Texas Advanced Computing Center at the University of Texas at Austin, United States, is an advanced computing research center that is based on comprehensive advanced computing resources and supports services to researchers in Texas and across the U.S. The mission of TACC is to enable discoveries that advance science and society through the application of advanced computing technologies. Specializing in high-performance computing, scientific visualization, data analysis and storage systems, software, research and development, and portal interfaces, TACC deploys and operates advanced computational infrastructure to enable the research activities of faculty, staff, and students of UT Austin. TACC also provides consulting, technical documentation, and training to support researchers who use these resources. TACC staff members conduct research and development in applications and algorithms, computing systems design/architecture, and programming tools and environments.
Founded in 2001, TACC is one of the centers of computational excellence in the United States. Through the National Science Foundation Extreme Science and Engineering Discovery Environment project, TACC's resources and services are made available to the national academic research community. TACC is located on UT's J. J. Pickle Research Campus.
TACC collaborators include researchers in other UT Austin departments and centers, at Texas universities in the , and at other U.S. universities and government laboratories.
Projects
TACC research and development activities are supported by several federal programs, including:NSF XSEDE (formerly [TeraGrid]) Program
Funded by the National Science Foundation, XSEDE is a virtual system that scientists can use to interactively share computing resources, data, and expertise. XSEDE is the most powerful and robust collection of integrated advanced digital resources and services in the world.TACC is one of the leading partners in the XSEDE project, whose resources include more than one petaflop of computing capability and more than 30 petabytes of online and archival data storage. As part of the project, TACC provides access to Ranger, Lonestar, Longhorn, Spur, and Ranch through XSEDE quarterly allocations. TACC staff members support XSEDE researchers nationwide, and perform research and development to make XSEDE more effective and impactful. The XSEDE partnership also includes: the University of Illinois at Urbana-Champaign, Carnegie Mellon University/University of Pittsburgh, University of Texas at Austin, University of Tennessee Knoxville, University of Virginia, Shodor Education Foundation, Southeastern Universities Research Association, University of Chicago, University of California San Diego, Indiana University, Jülich Supercomputing Centre, Purdue University, Cornell University, Ohio State University, University of California Berkeley, Rice University, and the National Center for Atmospheric Research. It is led by the University of Illinois's National Center for Supercomputing Applications. XSEDE concluded formal operations as a National Science Foundation funded project on August 31, 2022. Similar services are now operated through NSF's follow-on program, Advanced Cyberinfrastructure Coordination Ecosystem: Services & Support, or ACCESS.
University of Texas Research Cyberinfrastructure (UTRC) Project
The UT System Research Cyberinfrastructure Project is an initiative that allows researchers at all 15 UT System institutions to access advanced computing research infrastructure. As part of the UTRC, UT system researchers have unique access to TACC resources including TACC's Lonestar, a national XSEDE resource, and Corral, a high-performance storage system for all types of digital data.iPlant Collaborative
The iPlant Collaborative is a 5-year, 50 million-dollar NSF project that uses new computational science and cyberinfrastructure solutions to address challenges in the plant sciences. iPlant integrates high-performance petascale storage, federated identity management, on-demand virtualization, and distributed computing across XSEDE sites behind a set of REST APIs. These serve as the basis for presenting community-extensible rich web clients that enable the plant science community to perform sophisticated bioinformatics analyses across a variety of conceptual domains. In September 2013 it was announced that the NSF had renewed iPlant's funding for a second 5-year term with an expansion of scope to all non-human life science research.STAR Partners Program
The Science and Technology Affiliates for Research Program offers opportunities for companies to increase their effectiveness through utilizing TACC's computing technologies. Current STAR partners include corporations BP, Chevron, Dell, Green Revolution Cooling, Intel, and Technip.Digital Rocks Portal
A sustainable, open, and easy-to-use repository that organizes the images and related experimental measurements of diverse porous materials, improves access to porous media analysis results to a wider community of geosciences and engineering researchers not necessarily trained in computer science or data analysis, and enhances productivity, scientific inquiry, and engineering decisions founded on a data-driven basis.Supercomputer clusters
Stampede
Stampede was one of the most powerful machines in the world for open science research. Funded by the National Science Foundation Grant ACI-1134872 and built in partnership with Intel, Dell, and Mellanox, Stampede was stood up in September 2012, and brought online on January 7, 2013. Stampede comprised 6400 nodes, 102,400 CPU cores, 205 TB total memory, 14 PB total, and 1.6 PB local storage. The bulk of the cluster consisted of 160 racks of primary compute nodes, each with dual Xeon E5-2680 8-core processors, an Xeon Phi coprocessor, and 32 GB RAM. The cluster also contained 16 nodes with 32 cores and 1 TB each, 128 "standard" compute nodes with Nvidia Kepler K20 GPUs, and other nodes for I/O, login, and cluster management. Stampede could complete 9.6 quadrillion floating-point operations per second.A pre-production configuration of Stampede was listed as the seventh fastest supercomputer on the November 2012 Top500 list with a delivered performance of 2660 TFlops. Because the system was still being assembled, the submitted benchmark was run using 1875 nodes with Xeon Phi coprocessors and 3900 nodes without Xeon Phi coprocessors. For the June 2013 Top500 list, the benchmark was re-run using 6006 nodes, delivering 5168 TFlops and moving the system up to sixth place. The benchmark was not re-run for the November 2013 Top500 list and Stampede dropped back to the seventh position.
In its first year of production, Stampede completed 2,196,848 jobs by 3,400 researchers, performing more than 75,000 years of scientific computations.
In 2019, following the decommissioning of Stampede, the United States Federal Reserve took ownership of a significant chunk of Stampede, operating it as a cluster called BigTex, used for large-scale financial analysis. Another large chunk of Stampede was repurposed and used for Stampede2, the successor to Stampede, utilizing socketed Xeon Phi 'Knights Landing' processors, rather than the PCIe card 'Knights Corner' add-in cards that Stampede consisted of.
Maverick
Maverick, TACC's latest addition to its suite of advanced computing systems, combines capacities for interactive advanced visualization and large-scale data analytics as well as traditional high-performance computing. Recent exponential increases in the size and quantity of digital datasets necessitate new systems such as Maverick, capable of fast data movement and advanced statistical analysis. Maverick debuts the new NVIDIA K40 GPU for remote visualization and GPU computing to the national community.Visualization:
- 132 NVIDIA Tesla K40 GPUs
- TACC-developed remote vis software: ScoreVIS, DisplayCluster, GLuRay, and more
- Visualization software stack: Paraview, VisIT, EnSight, Amira, and more
- 132 1/4TB memory nodes
- connected to 20PB file system
- Mellanox FDR InfiniBand interconnect
- comprehensive software includes: MATLAB, Parallel R, and more
Lonestar
The first Lonestar system was built by Dell and integrated by Cray, using Dell PowerEdge 1750 servers and Myrinet interconnects, with a peak performance of 3672 gigaFlops. An upgrade in 2004 increased the number of processors to 1024 and the peak rate of 6338 gigaflops. The second iteration in 2006 was deployed with Dell PowerEdge 1855 servers and Infiniband. Later that year, the cluster's third iteration was built from Dell PowerEdge 1955 servers; it was composed of 5200 processors and 10.4 TB memory. Lonestar 3 entered the Top500 list in November 2006 as the twelfth fastest supercomputer, with 55.5 TFlops peak.
In April 2011, TACC announced another upgrade of the Lonestar cluster. The $12 million Lonestar 4 cluster replaced its predecessor with 1,888 Dell M610 PowerEdge blade servers, each with two six-core Intel Xeon 5600 processors. The system storage includes a 1000TB parallel Lustre file system, and 276TB of local compute-node disk space. Lonestar also provides access to five large memory nodes, and eight nodes containing two NVIDIA GPUs, giving users access to high-throughput computing and remote visualization capabilities respectively.
Lonestar 4 entered the Top500 list in June 2011 as the 28th fastest supercomputer, with 301.8 TFlops peak.
The Top500 rankings of various iterations of the Lonestar cluster are listed in TACC's submissions to the Top500.