Related papers: Qubit Energy Tuner Based on Single Flux Quantum Circuits

Qubit Energy Tuner Based on Single Flux Quantum Circuits

URL: http://arxiv.org/abs/2303.02299v1
Date: Sat, 4 Mar 2023 02:43:40 GMT
Title: Qubit Energy Tuner Based on Single Flux Quantum Circuits
Authors: Xiao Geng, Rutian Huang, Yongcheng He, Kaiyong He, Genting Dai, Liangliang Yang, Xinyu Wu, Qing Yu, Mingjun Cheng, Guodong Chen, Jianshe Liu and Wei Chen
Abstract summary: A device called qubit energy tuner (QET) based on single flux quantum (SFQ) circuits is proposed for Z control of superconducting qubits. The key feature of a QET is analyzed to understand how SFQ pulses change the inductor loop current, which provides external flux for qubits.
Score: 12.413283470289782
License: http://creativecommons.org/licenses/by-nc-sa/4.0/
Abstract: A device called qubit energy tuner (QET) based on single flux quantum (SFQ) circuits is proposed for Z control of superconducting qubits. Created from the improvement of flux digital-to-analog converters (flux DACs), a QET is able to set the energy levels or the frequencies of qubits, especially flux-tunable transmons, and perform gate operations requiring Z control. The circuit structure of QET is elucidated, which consists of an inductor loop and flux bias units for coarse tuning or fine tuning. The key feature of a QET is analyzed to understand how SFQ pulses change the inductor loop current, which provides external flux for qubits. To verify the functionality of the QET, three simulations are carried out. The first one verifies the responses of the inductor loop current to SFQ pulses. The results show that there is about 4.2% relative deviation between analytical solutions of the inductor loop current and the solutions from WRSpice time-domain simulation. The second and the third simulations with QuTip show how a Z gate and an iSWAP gate can be performed by this QET, respectively, with corresponding fidelities 99.99884% and 99.93906% for only once gate operation to specific initial states. These simulations indicate that the SFQ-based QET could act as an efficient component of SFQ-based quantum-classical interfaces for digital Z control of large-scale superconducting quantum computers.

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