RSFQ All-Digital Programmable Multitone Generator for Quantum Applications

IEEE Transactions on Quantum Engineering Pub Date : 2024-12-20 DOI:10.1109/TQE.2024.3520805

João Barbosa;Jack C. Brennan;Alessandro Casaburi;M. D. Hutchings;Alex Kirichenko;Oleg Mukhanov;Martin Weides

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Abstract

One of the most important and topical challenges of quantum circuits is their scalability. Rapid single flux quantum (RSFQ) technology is at the forefront of replacing current standard CMOS-based control architectures for a number of applications, including quantum computing and quantum sensor arrays. By condensing the control and readout to single-flux-quantum-based on-chip devices that are directly connected to the quantum systems, it is possible to minimize the total system overhead, improving scalability and integration. In this article, we present a novel RSFQ device that generates multitone digital signals, based on complex pulse train sequences using a circular shift register (CSR) and a comb filter stage. We show that the frequency spectrum of the pulse trains is dependent on a preloaded pattern on the CSR, as well as on the delay line of the comb filter stage. By carefully selecting both the pattern and delay, the desired tones can be isolated and amplified as required. Finally, we propose architectures where this device can be implemented to control and read out arrays of quantum devices, such as qubits and single-photon detectors.

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用于量子应用的RSFQ全数字可编程多音发生器

量子电路最重要和最热门的挑战之一是其可扩展性。快速单通量量子（RSFQ）技术在量子计算和量子传感器阵列等许多应用中取代了当前基于cmos的标准控制体系结构。通过将控制和读出压缩到直接连接到量子系统的基于单通量量子的片上设备，可以最大限度地减少总系统开销，提高可扩展性和集成度。在这篇文章中，我们提出了一种新的RSFQ装置，它产生多音数字信号，基于复杂的脉冲序列序列，使用圆移位寄存器（CSR）和梳状滤波器级。我们表明，脉冲序列的频谱依赖于CSR上的预加载模式，以及梳状滤波器级的延迟线。通过仔细选择模式和延迟，可以根据需要隔离和放大所需的音调。最后，我们提出了可以实现该器件的架构，以控制和读出量子器件阵列，例如量子比特和单光子探测器。

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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