Tech Unveils Powerful New Supercomputer for the Masses

Wu Feng, associate professor of computer science and electrical and computer engineering, at one of the dozens of nodes of "HokieSpeed,”,Virginia Tech's latest and fastest entry into the supercomputing arena.

by Steven Mackey

Virginia Tech crashed the supercomputing arena in 2003 with System X, a machine that placed the university among the world’s top computational research facilities. Now comes HokieSpeed, a new supercomputer that is up to 22 times faster and yet a quarter of the size of X, boasting a single-precision peak of 455 teraflops, or 455 trillion operations per second, and a double-precision peak of 240 teraflops, or 240 trillion operations per second.

That’s enough computational capability to place HokieSpeed at No. 96 on the most recent Top500 List, the industry-standard ranking of the world’s 500 fastest supercomputers. More intriguing is HokieSpeed’s energy efficiency, which ranks it at No. 11 in the world on the November 2011 Green500 List, a compilation of supercomputers that excel at using less energy to do more. On the Green500 List, HokieSpeed is the highest-ranked commodity supercomputer in the United States.

Located at Virginia Tech’s Corporate Research Center, HokieSpeed – contains 209 nodes, or separate computers, connected to one another in and across large metal racks, each roughly 6.5 feet tall, to create a single supercomputer that occupies half a row of racks in a vast university computer machine room. X took three times the rack space.

Each HokieSpeed node contains two 2.40-gigahertz Intel Xeon E5645 6-core central processing units, commonly called CPUs, and two NVIDIA M2050/C2050 448-core graphics processor units, or GPUs, which reside on a Supermicro 2026GT0TRF motherboard. That gives HokieSpeed more than 2,500 central processing unit cores and more than 185,000 graphics processor unit cores to compute with.

HokieSpeed is a versatile heterogeneous supercomputing instrument, where each compute node consists of energy-efficient central-processing units and high-end graphics-processing units, said Wu Feng, associate professor with the Virginia Tech College of Engineering’s computer science and electrical and computer engineering departments.

This instrument will allow faculty, students and staff across multiple disciplines to tackle problems previously viewed as intractable or that required heroic efforts and significant domain-specic expertise to solve.

Still in the final stages of acceptance testing, Feng envisions HokieSpeed as Virginia Tech’s next war horse in research. As researchers from around the world have used X to crack riddles of the blood system and further DNA research, Feng said HokieSpeed will be a next-generation research tool for engineers, scientists, and others.

HokieSpeed was built for $1.4 million, a small fraction — one-tenth of a percent of the cost — of the Top500’s current No. 1 supercomputer, the K Computer from Japan. The majority of funding for HokieSpeed came from a $2 million National Science Foundation Major Research Instrumentation grant. With federal and state budget crunches here to stay, Feng said HokieSpeed carries another plus: It can attract more international research projects to Virginia Tech, adding more to the College of Engineering’s income.

Among the vendors working with Feng on HokieSpeed are Seneca Data Inc. and Super Micro Computer Inc., who were the driving force behind the project, as well as NVIDIA Corp., for their technical support. Feng has worked with NVIDIA before, with the Silicon Valley-based technology firm naming Virginia Tech as a research center and the NVIDIA Foundation’s first worldwide research award for computing the cure for cancer being awarded to Feng.

In addition to HokieSpeed’s compute nodes, a visualization wall – eight 46-inch, 3-D Samsung high-definition flat-screen televisions – will provide a 14-foot wide by 4-foot tall display for end-users to be immersed in their data. Still under construction, the visualization wall will be hooked-up to special visualization nodes built into HokieSpeed and allow researchers to perform in-situ visualization.

This way, researchers can see in real-time if their computational experiment is turning out as expected, or if corrections or on-the-fly adjustments must be made, said Feng. Previously, weeks could pass by before all the data from a computational experiment was generated and then rendered as a video for viewing and analysis.

For now, high-tech universities, government research labs, and major corporations use supercomputers on a regular basis, major organizations from the MIT to the Pentagon to Hollywood movie companies. As supercomputers such as HokieSpeed grow in brain size and diversity, and yet shrink in space, they will become more readily available to the public at large, said Feng. That is his ultimate goal.

“Look at what Apple has done with the smartphone and iPad. They have taken general-purpose computing and commoditized it and made it easy to use for the masses,” said Feng. The next frontier is to take high-performance computing, in particular supercomputers such as HokieSpeed, and personalize it for the masses.

Such access to supercomputers could help small businesses that do not have multi-billion-dollar budgets for cyberinfrastructure, to better design their products or the process in which their products are produced on the assembly line in the factory. Scientists at smaller universities could use supercomputers for their own research efforts.

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