Integration of Quantum Accelerators with High Performance Computing -- A
Review of Quantum Programming Tools
- URL: http://arxiv.org/abs/2309.06167v2
- Date: Mon, 18 Sep 2023 08:02:54 GMT
- Title: Integration of Quantum Accelerators with High Performance Computing -- A
Review of Quantum Programming Tools
- Authors: Amr Elsharkawy, Xiao-Ting Michelle To, Philipp Seitz, Yanbin Chen,
Yannick Stade, Manuel Geiger, Qunsheng Huang, Xiaorang Guo, Muhammad Arslan
Ansari, Christian B. Mendl, Dieter Kranzlm\"uller, and Martin Schulz
- Abstract summary: This study aims to characterize existing quantum programming tools (QPTs) from an HPC perspective.
It investigates if existing QPTs have the potential to be efficiently integrated with classical computing models.
This work structures a set of criteria into an analysis blueprint that enables HPC scientists to assess whether a QPT is suitable for the quantum-accelerated classical application.
- Score: 0.8477185635891722
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Quantum computing (QC) introduces a novel mode of computation with the
possibility of greater computational power that remains to be exploited -
presenting exciting opportunities for high performance computing (HPC)
applications. However, recent advancements in the field have made clear that QC
does not supplant conventional HPC, but can rather be incorporated into current
heterogeneous HPC infrastructures as an additional accelerator, thereby
enabling the optimal utilization of both paradigms. The desire for such
integration significantly affects the development of software for quantum
computers, which in turn influences the necessary software infrastructure. To
date, previous review papers have investigated various quantum programming
tools (QPTs) (such as languages, libraries, frameworks) in their ability to
program, compile, and execute quantum circuits. However, the integration effort
with classical HPC frameworks or systems has not been addressed. This study
aims to characterize existing QPTs from an HPC perspective, investigating if
existing QPTs have the potential to be efficiently integrated with classical
computing models and determining where work is still required. This work
structures a set of criteria into an analysis blueprint that enables HPC
scientists to assess whether a QPT is suitable for the quantum-accelerated
classical application at hand.
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