Comparing the Orchestration of Quantum Applications on Hybrid Clouds

2023 IEEE/ACM 23rd International Symposium on Cluster, Cloud and Internet Computing Workshops (CCGridW) Pub Date : 2023-05-01 DOI:10.1109/CCGridW59191.2023.00069

Rajiv Sangle, Tuhin Khare, P. V. Seshadri, Yogesh L. Simmhan

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引用次数: 1

Abstract

Early quantum computers are being offered by Cloud providers, with the ability to run Hybrid Quantum-Classical (HQC) applications that span Quantum and Classical (binary) computing resources. These HQC algorithms help benchmark and validate the performance of such near-term quantum hardware. Equally important is the software platform that allows a remote user to program the quantum computer on the cloud. The recent Qiskit Runtime platform from IBM allows a seamless and prioritized access to quantum backends and co-located classical hardware within their hybrid cloud for optimized execution of HQC workloads. In contrast, IBM’s Circuit API offers finer application definition but the classical resources are not co-located but placed farther away. Here, we study and contrast the execution flows of a Variational Quantum Eigensolver (VQE) application defined using Qiskit Runtime, and an equivalent implementation using the Circuit API. We quantify the latencies of the various components in these execution. This offers insights on how to better orchestrate the execution of quantum applications across such hybrid resources.

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混合云上量子应用编排的比较

早期的量子计算机由云提供商提供，能够运行跨越量子和经典(二进制)计算资源的混合量子-经典(HQC)应用程序。这些HQC算法有助于对这些近期量子硬件的性能进行基准测试和验证。同样重要的是软件平台，它允许远程用户在云端对量子计算机进行编程。IBM最近推出的Qiskit Runtime平台允许对量子后端和混合云中的经典硬件进行无缝和优先级访问，以优化HQC工作负载的执行。相比之下，IBM的Circuit API提供了更精细的应用程序定义，但经典资源不是放在一起，而是放在更远的地方。在这里，我们研究并对比了使用Qiskit Runtime定义的变分量子特征求解器(VQE)应用程序的执行流程，以及使用Circuit API的等效实现。我们量化了这些执行中各个组件的延迟。这为如何更好地协调跨此类混合资源的量子应用程序的执行提供了见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2023 IEEE/ACM 23rd International Symposium on Cluster, Cloud and Internet Computing Workshops (CCGridW)

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