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NVIDIA And National Taiwan University Aim To Unlock The Secrets Of The Universe


NTU achieves breakthrough results in sub-atomic particle calculations at 1% the cost and 10% the power consumption of a BlueGene/L supercomputer.

Taipei, Taiwan, A research team at National Taiwan University (NTU) is achieving breakthrough results in learning about the early evolution of the universe by harnessing NVIDIA® Tesla™ parallel processors -- which provide the computational horsepower of an IBM BlueGene/L supercomputer, at just 1% the cost and 10% the power consumption.

The team, led by Ting-Wai Chiu, Professor of Physics and Associate Director of the Center for Quantum Science and Engineering (CQSE), is studying the interactions of sub-atomic particles, to learn about the origins of the universe, which requires enormous computational power.

NTU is carrying out this work on the first GPU-based supercomputer in Taiwan, the 128-GPU cluster at CQSE, which uses 16 NVIDIA Tesla S1070 1U systems and 64 Tesla C1060 processors. The system plays a key role in large-scale computations for quantum physics, ranging from the strong interaction at the subatomic scale to the strongly correlated electrons in condensed matter physics, and to the cosmology at the astronomical scale.

“We are excited to see our GPU-based cluster outperform many conventional supercomputers in both cost and energy use,” said Chiu. “With our GPU-enabled supercomputer, we are delivering 15 teraflops at a price of US$200,000, 1% the cost of a conventional supercomputer like IBM BlueGene/L.”

“It’s deeply rewarding to see NVIDIA Tesla GPUs helping professionals and researchers achieve amazing breakthroughs in their work,” said Andy Keane, general manager, Tesla business, NVIDIA. “The exceptional speed-up being seen by NTU has the ability to dramatically accelerate the research into one of life’s biggest and most complex scientific challenges.”

NVIDIA Tesla GPUs are based on CUDA™, NVIDIA’s computing architecture that enables its GPUs to be programmed using industry standard programming languages and APIs, opening up their massive parallel processing power to a broad range of applications beyond graphics. The CQSE has developed highly efficient CUDA-optimized codes for the computationally challenging problems in QCD, quantum spin systems, and astrophysics.

In addition, the lattice QCD group (TWQCD) based at National Taiwan University is now the first group in the world to use a GPU cluster to perform large-scale simulations of lattice QCD with exact chiral symmetry.


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