Analyzing Machine Learning Performance in a Hybrid Quantum Computing and HPC Environment
Bieberich, Samuel T., Sandoval, Michael A.
–arXiv.org Artificial Intelligence
We explored the possible benefits of integrating quantum simulators in a "hybrid" quantum machine learning (QML) workflow that uses both classical and quantum computations in a high-performance computing (HPC) environment. Here, we used two Oak Ridge Leadership Computing Facility HPC systems, Andes (a commodity-type Linux cluster) and Frontier (an HPE Cray EX supercomputer), along with quantum computing simulators from PennyLane and IBMQ to evaluate a hybrid QML program -- using a "ground up" approach. Using 1 GPU on Frontier, we found ~56% and ~77% speedups when compared to using Frontier's CPU and a local, non-HPC system, respectively. Analyzing performance on a larger dataset using multiple threads, the Frontier GPUs performed ~92% and ~48% faster than the Andes and Frontier CPUs, respectively. More impressively, this is a ~226% speedup over a local, non-HPC system's runtime using the same simulator and number of threads. We hope that this proof of concept will motivate more intensive hybrid QC/HPC scaling studies in the future.
arXiv.org Artificial Intelligence
Jul-9-2024
- Country:
- North America > United States
- Texas > Brazos County
- College Station (0.04)
- Tennessee > Anderson County
- Oak Ridge (0.04)
- Texas > Brazos County
- North America > United States
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- Scientific Computing (1.00)
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- Artificial Intelligence > Machine Learning (1.00)
- Information Technology