An FPGA-Based Low Latency AWG for Superconducting Quantum Computers

Yuchen Yang, Z. Shen, Xing Zhu, Chunqing Deng, Shubin Liu, Q. An
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Abstract

This paper reports the development of a low-latency arbitrary waveform generator (AWG), which is suitable for the control and measurement of superconducting quantum computers. It can generate qubit control signals and measurement signals in real time. Compared with commercial AWG, our AWG has less latency and higher analog bandwidth. Compressing latency can reduce system feedback time, and higher analog bandwidth improves the system's integration by mounting more qubits on the readout line. The AWG integrates four high-speed digital-to-analog converters (DACs), phase-locked loop (PLL) circuits, field-programmable gate arrays (FPGAs), and related circuits into a standard PXI 3U board. The waveform generator module, communication interface module, clock module, and configuration module are realized utilizing the FPGA. The FPGA-based hardware architecture enables AWG to be flexibly configured to meet the various needs of quantum experiments. The four-channel AWG has a 2-GSa/s sampling rate, a 14-bit resolution, and 500 MHz bandwidth. The jitter in the AWG output waveform is approximately 3 ps; the latency of the AWG (the time from the feedback trigger received until a feedback pulse is generated) is approximately 55 ns. These designs form the basis of realizing control system for large-scale quantum computing.
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基于fpga的超导量子计算机低延迟AWG
本文报道了一种适用于超导量子计算机控制和测量的低延迟任意波形发生器(AWG)的研制。它可以实时生成量子位控制信号和测量信号。与商用AWG相比,我们的AWG具有更低的延迟和更高的模拟带宽。压缩延迟可以减少系统反馈时间,更高的模拟带宽通过在读出线上安装更多的量子比特来提高系统的集成度。AWG将四个高速数模转换器(dac)、锁相环(PLL)电路、现场可编程门阵列(fpga)和相关电路集成到一个标准的PXI 3U板中。利用FPGA实现了波形产生模块、通信接口模块、时钟模块和组态模块。基于fpga的硬件架构使AWG能够灵活配置,以满足量子实验的各种需求。四通道AWG具有2gsa /s采样率,14位分辨率和500mhz带宽。AWG输出波形的抖动约为3ps;AWG的延迟(从收到反馈触发器到产生反馈脉冲的时间)大约为55 ns。这些设计构成了实现大规模量子计算控制系统的基础。
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