A Hardware-Accelerated Qubit Control System for Quantum Information Processing

2020 XXXV Conference on Design of Circuits and Integrated Systems (DCIS) Pub Date : 2020-11-18 DOI:10.1109/DCIS51330.2020.9268643

N. Messaoudi, C. Crocker, M. Almendros

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引用次数: 1

Abstract

In this paper we present a flexible, highperformance, integrated qubit control system using modular PXIe equipment. To manipulate qubits, a classical control system is required to generate and acquire a mix of baseband, radio frequency, and/or optical signals, with the specific mix different for each qubit technology. Typically, a quantum system requires many of these signals with a high degree of synchronization and phase coherence, and increasingly needs real-time data processing and on-the-fly sequencing capabilities for feedback experiments. The proposed system is scalable to hundreds of channels, all of them being phase coherent and fully time-synchronized.The system includes a programmable real-time sequencer for precise execution timing and decision making; and open FPGA capabilities for custom Digital Signal Processing (DSP) by hardware. Using the latter, we present FPGA IP to generate one-/two-qubit gates efficiently with the AWG, and to analyze high-frequency signals to measure the qubit states in real time on the digitizers. This IP features very low latencies for Quantum Error Correction (QEC) and Frequency Division Multiplexing (FDM) capabilities, among others.

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量子信息处理的硬件加速量子比特控制系统

在本文中，我们提出了一个灵活的，高性能的集成量子比特控制系统，使用模块化PXIe设备。为了操纵量子比特，需要一个经典的控制系统来生成和获取基带、射频和/或光学信号的混合，每种量子比特技术的具体混合是不同的。通常，量子系统需要许多具有高度同步和相位相干性的信号，并且越来越需要实时数据处理和实时排序能力来进行反馈实验。该系统可扩展到数百个通道，所有通道都是相位相干和完全时间同步的。该系统包括一个可编程的实时序列器，用于精确的执行时序和决策;和开放的FPGA功能，可通过硬件定制数字信号处理(DSP)。对于后者，我们提出了FPGA IP，利用AWG高效地生成一个/两个量子比特的门，并分析高频信号，实时测量数字化仪上的量子比特状态。该IP在量子纠错(QEC)和频分复用(FDM)功能等方面具有非常低的延迟。

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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2020 XXXV Conference on Design of Circuits and Integrated Systems (DCIS)

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