Optimizing for periodicity: a model-independent approach to flux crosstalk calibration for superconducting circuits

Flux tunability is an important engineering resource for superconducting circuits. Large-scale quantum computers based on flux-tunable superconducting circuits face the problem of flux crosstalk, which needs to be accurately calibrated to realize high-fidelity quantum operations. Typical calibration...

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Veröffentlicht in:	arXiv.org 2024-02
Hauptverfasser:	Dai, X, Trappen, R, Yang, R, Disseler, S M, Basham, J I, Gibson, J, Melville, A J, Niedzielski, B M, Das, R, Kim, D K, Yoder, J L, Weber, S J, Hirjibehedin, C F, Lidar, D A, Lupascu, A
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Schlagworte:	Calibration Circuits Crosstalk Optimization Physics - Quantum Physics Quantum computers Qubits (quantum computing) Superconductivity
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creator	Dai, X Trappen, R Yang, R Disseler, S M Basham, J I Gibson, J Melville, A J Niedzielski, B M Das, R Kim, D K Yoder, J L Weber, S J Hirjibehedin, C F Lidar, D A Lupascu, A
description	Flux tunability is an important engineering resource for superconducting circuits. Large-scale quantum computers based on flux-tunable superconducting circuits face the problem of flux crosstalk, which needs to be accurately calibrated to realize high-fidelity quantum operations. Typical calibration methods either assume that circuit elements can be effectively decoupled and simple models can be applied, or require a large amount of data. Such methods become ineffective as the system size increases and circuit interactions become stronger. Here we propose a new method for calibrating flux crosstalk, which is independent of the underlying circuit model. Using the fundamental property that superconducting circuits respond periodically to external fluxes, crosstalk calibration of N flux channels can be treated as N independent optimization problems, with the objective functions being the periodicity of a measured signal depending on the compensation parameters. We demonstrate this method on a small-scale quantum annealing circuit based on superconducting flux qubits, achieving comparable accuracy with previous methods. We also show that the objective function usually has a nearly convex landscape, allowing efficient optimization.
doi_str_mv	10.48550/arxiv.2211.01497
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subjects	Calibration Circuits Crosstalk Optimization Physics - Quantum Physics Quantum computers Qubits (quantum computing) Superconductivity
title	Optimizing for periodicity: a model-independent approach to flux crosstalk calibration for superconducting circuits
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