NVIDIA has announced its collaboration with the Pawsey Supercomputing Research Centre to bring the power of NVIDIA CUDA Quantum to the National Supercomputing and Quantum Computing Innovation Hub in Perth, Australia. This partnership aims to drive advancements in quantum computing research and pave the way for breakthroughs in various scientific fields.
NVIDIA CUDA Quantum is an open-source hybrid quantum computing platform that operates on NVIDIA Grace Hopper Superchips. With its robust simulation tools and the ability to program hybrid CPU, GPU, and QPU systems, CUDA Quantum offers researchers optimized libraries and tools to fast-track quantum computing workflows.
By leveraging the capabilities of the NVIDIA Grace Hopper Superchips, innovators and researchers at Pawsey will be able to accelerate their efforts to address the most significant challenges in quantum computing. They will have the opportunity to explore algorithm discovery, device design, and the development of powerful methods for error correction and control.
The deployment of eight nodes equipped with NVIDIA Grace Hopper Superchips based on the NVIDIA MGX modular architecture will enable Pawsey to push the boundaries of what is possible in quantum computing research. These GH200 Superchips combine an Arm-based NVIDIA Grace CPU with an NVIDIA H100 Tensor Core GPU, eliminating the need for traditional CPU-to-GPU PCIe connections and significantly increasing bandwidth between the GPU and CPU.
The collaboration between NVIDIA and Pawsey will not only drive advancements in quantum computing but also have a significant impact on various scientific domains. Fields such as astronomy, life sciences, medicine, and finance are expected to benefit from the innovations and breakthroughs enabled by this powerful computing technology.
With the NVIDIA CUDA Quantum platform, Pawsey scientists will have the capability to run quantum workloads directly from traditional high-performance computing systems. They will develop hybrid algorithms that optimize computing efficiency by dividing calculations into classical and quantum kernels, enabling them to tackle complex problems efficiently.
This partnership between NVIDIA and Pawsey marks a significant step forward in the quantum computing research landscape, bringing together cutting-edge technology and the expertise of researchers to accelerate quantum innovation and drive advancements in scientific fields across Australia and beyond.
FAQ
1. What is NVIDIA’s collaboration with the Pawsey Supercomputing Research Centre?
NVIDIA has announced its collaboration with the Pawsey Supercomputing Research Centre to bring the power of NVIDIA CUDA Quantum to the National Supercomputing and Quantum Computing Innovation Hub in Perth, Australia. This partnership aims to drive advancements in quantum computing research and pave the way for breakthroughs in scientific fields.
2. What is NVIDIA CUDA Quantum?
NVIDIA CUDA Quantum is an open-source hybrid quantum computing platform that operates on NVIDIA Grace Hopper Superchips. It offers robust simulation tools and the ability to program hybrid CPU, GPU, and QPU systems. CUDA Quantum provides optimized libraries and tools to fast-track quantum computing workflows.
3. What are the capabilities of the NVIDIA Grace Hopper Superchips?
The NVIDIA Grace Hopper Superchips, based on the NVIDIA MGX modular architecture, enable accelerated quantum computing research. These Superchips combine an Arm-based NVIDIA Grace CPU with an NVIDIA H100 Tensor Core GPU, increasing the bandwidth between the GPU and CPU and eliminating the need for traditional CPU-to-GPU PCIe connections.
4. How will this collaboration benefit quantum computing research?
The collaboration between NVIDIA and Pawsey will allow researchers to accelerate their efforts in quantum computing. They will have the opportunity to explore algorithm discovery, device design, and the development of methods for error correction and control. The deployment of eight nodes equipped with NVIDIA Grace Hopper Superchips will push the boundaries of what is possible in quantum computing research.
5. Which scientific domains will benefit from this collaboration?
Fields such as astronomy, life sciences, medicine, and finance are expected to benefit from the innovations and breakthroughs enabled by this powerful computing technology. The advancements in quantum computing research will have a significant impact on various scientific domains.
Definitions:
– NVIDIA CUDA Quantum: An open-source hybrid quantum computing platform that operates on NVIDIA Grace Hopper Superchips, providing optimized tools and libraries for quantum computing workflows.
– NVIDIA Grace Hopper Superchips: Superchips based on the NVIDIA MGX modular architecture that combine an Arm-based NVIDIA Grace CPU with an NVIDIA H100 Tensor Core GPU, enabling accelerated quantum computing research.
– Quantum computing: A field of computing that utilizes the principles of quantum mechanics to perform calculations, aiming to solve complex problems more efficiently than traditional computing methods.
– Pawsey Supercomputing Research Centre: A research center in Perth, Australia, focused on high-performance computing and providing advanced facilities and services to support various research fields.
Suggested Related Links:
– NVIDIA
– Pawsey Supercomputing Research Centre
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