Automatic Qubit Characterization and Gate Optimization with QubiC

ACM Transactions on Quantum Computing Pub Date : 2021-04-22 DOI:10.1145/3529397

Yilun Xu, Gang-Ming Huang, J. Balewski, A. Morvan, Kasra Nowrouzi, D. Santiago, R. Naik, B. Mitchell, I. Siddiqi

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引用次数: 6

Abstract

As the size and complexity of a quantum computer increases, quantum bit (qubit) characterization and gate optimization become complex and time-consuming tasks. Current calibration techniques require complicated and verbose measurements to tune up qubits and gates, which cannot easily expand to the large-scale quantum systems. We develop a concise and automatic calibration protocol to characterize qubits and optimize gates using QubiC, which is an open source FPGA (field-programmable gate array)-based control and measurement system for superconducting quantum information processors. We propose multi-dimensional loss-based optimization of single-qubit gates and full XY-plane measurement method for the two-qubit CNOT gate calibration. We demonstrate the QubiC automatic calibration protocols are capable of delivering high-fidelity gates on the state-of-the-art transmon-type processor operating at the Advanced Quantum Testbed at Lawrence Berkeley National Laboratory. The single-qubit and two-qubit Clifford gate infidelities measured by randomized benchmarking are of 4.9(1.1) × 10-4 and 1.4(3) × 10-2, respectively.

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基于QubiC的自动量子比特表征和门优化

随着量子计算机的尺寸和复杂性的增加，量子比特(qubit)表征和门优化成为复杂而耗时的任务。目前的校准技术需要复杂和冗长的测量来调整量子位和门，这很难扩展到大规模的量子系统。我们开发了一种简洁的自动校准协议来表征量子比特并使用QubiC优化门，QubiC是一种基于开源FPGA(现场可编程门阵列)的超导量子信息处理器控制和测量系统。我们提出了基于多维损耗的单量子位栅极优化和双量子位CNOT栅极校准的全xy平面测量方法。我们演示了QubiC自动校准协议能够在劳伦斯伯克利国家实验室先进量子试验台运行的最先进的transon型处理器上提供高保真门。随机基准测试的单量子位和双量子位Clifford gate不信度分别为4.9(1.1)× 10-4和1.4(3)× 10-2。

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ACM Transactions on Quantum Computing

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