Understanding Quantum Control Processor Capabilities and Limitations through Circuit Characterization

2020 International Conference on Rebooting Computing (ICRC) Pub Date : 2019-09-25 DOI:10.1109/ICRC2020.2020.00011

Anastasiia Butko, George Michelogiannakis, Samuel Williams, Costin Iancu, D. Donofrio, J. Shalf, J. Carter, I. Siddiqi

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引用次数: 24

Abstract

Continuing the scaling of quantum computers hinges on building classical control hardware pipelines that are scalable, extensible, and provide real time response. The instruction set architecture (ISA) of the control processor provides functional abstractions that map high-level semantics of quantum programming languages to low-level pulse generation by hardware. In this paper, we provide a methodology to quantitatively assess the effectiveness of the ISA to encode quantum circuits for intermediate-scale quantum devices with O(102) qubits. The characterization model that we define reflects performance, the ability to meet timing constraint implications, scalability for future quantum chips, and other important considerations making them useful guides for future designs. Using our methodology, we propose scalar (QUASAR) and vector (qV) quantum ISAs as extensions and compare them with other ISAs in metrics such as circuit encoding efficiency, the ability to meet real-time gate cycle requirements of quantum chips, and the ability to scale to more qubits.

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通过电路表征了解量子控制处理器的能力和局限性

量子计算机的持续扩展取决于构建可伸缩、可扩展并提供实时响应的经典控制硬件管道。控制处理器的指令集体系结构(ISA)提供了功能抽象，将量子编程语言的高级语义映射到硬件的低级脉冲生成。在本文中，我们提供了一种方法来定量评估ISA在0(102)量子比特的中等规模量子器件中编码量子电路的有效性。我们定义的表征模型反映了性能、满足时间约束的能力、未来量子芯片的可扩展性，以及其他重要的考虑因素，使它们成为未来设计的有用指南。使用我们的方法，我们提出标量(QUASAR)和矢量(qV)量子isa作为扩展，并将它们与其他isa在电路编码效率、满足量子芯片实时门周期要求的能力以及扩展到更多量子位的能力等指标进行比较。

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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来源期刊

2020 International Conference on Rebooting Computing (ICRC)

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