NVIDIA announced it is working with Google Quantum AI to
accelerate the design of its next-generation quantum computing devices
using simulations powered by the
NVIDIA CUDA-Q platform.
Google Quantum AI is using the hybrid quantum-classical computing
platform and the NVIDIA Eos supercomputer to simulate the physics of its
quantum processors. This will help overcome the current limitations of
quantum computing hardware, which can only run a certain number of
quantum operations before computations must cease, due to what
researchers call "noise."
"The development of commercially useful quantum computers is only
possible if we can scale up quantum hardware while keeping noise in
check," said Guifre Vidal, research scientist from Google Quantum AI.
"Using NVIDIA accelerated computing, we're exploring the noise
implications of increasingly larger quantum chip designs."
Understanding noise in quantum hardware designs requires complex
dynamical simulations capable of fully capturing how qubits within a
quantum processor interact with their environment.
These simulations have traditionally been prohibitively
computationally expensive to pursue. Using the CUDA-Q platform, however,
Google can employ 1,024 NVIDIA H100 Tensor Core GPUs
at the NVIDIA Eos supercomputer to perform one of the world's largest
and fastest dynamical simulation of quantum devices - at a fraction of
the cost.
"AI supercomputing power will be helpful to quantum computing's
success," said Tim Costa, director of quantum and HPC at NVIDIA.
"Google's use of the CUDA-Q platform demonstrates the central role
GPU-accelerated simulations have in advancing quantum computing to help
solve real-world problems."
With CUDA-Q and H100 GPUs, Google can perform fully comprehensive,
realistic simulations of devices containing 40 qubits - the
largest-performed simulations of this kind. The simulation techniques
provided by CUDA-Q mean noisy simulations that would have taken a week
can now run in minutes.
The software powering these accelerated dynamic simulations will be
publicly available in the CUDA-Q platform, allowing quantum hardware
engineers to rapidly scale their system designs.