Ray-based framework for state identification in quantum dot devices

Quantum dots (QDs) defined with electrostatic gates are a leading platform for a scalable quantum computing implementation. However, with increasing numbers of qubits, the complexity of the control parameter space also grows. Traditional measurement techniques, relying on complete or near-complete e...

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Veröffentlicht in:	arXiv.org 2021-06
Hauptverfasser:	Zwolak, Justyna P, McJunkin, Thomas, Kalantre, Sandesh S, Neyens, Samuel F, MacQuarrie, E R, Eriksson, Mark A, Taylor, Jacob M
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Sprache:	eng
Schlagworte:	Computer Science - Learning Gates Image classification Machine learning Measurement techniques Optimization Parameters Physics - Quantum Physics Quantum computing Quantum dots Qubits (quantum computing) Time measurement
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description	Quantum dots (QDs) defined with electrostatic gates are a leading platform for a scalable quantum computing implementation. However, with increasing numbers of qubits, the complexity of the control parameter space also grows. Traditional measurement techniques, relying on complete or near-complete exploration via two-parameter scans (images) of the device response, quickly become impractical with increasing numbers of gates. Here we propose to circumvent this challenge by introducing a measurement technique relying on one-dimensional projections of the device response in the multidimensional parameter space. Dubbed the ``ray-based classification (RBC) framework,'' we use this machine learning approach to implement a classifier for QD states, enabling automated recognition of qubit-relevant parameter regimes. We show that RBC surpasses the 82 % accuracy benchmark from the experimental implementation of image-based classification techniques from prior work while reducing the number of measurement points needed by up to 70 %. The reduction in measurement cost is a significant gain for time-intensive QD measurements and is a step forward toward the scalability of these devices. We also discuss how the RBC-based optimizer, which tunes the device to a multiqubit regime, performs when tuning in the two-dimensional and three-dimensional parameter spaces defined by plunger and barrier gates that control the QDs.This work provides experimental validation of both efficient state identification and optimization with machine learning techniques for non-traditional measurements in quantum systems with high-dimensional parameter spaces and time-intensive measurements.
doi_str_mv	10.48550/arxiv.2102.11784
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subjects	Computer Science - Learning Gates Image classification Machine learning Measurement techniques Optimization Parameters Physics - Quantum Physics Quantum computing Quantum dots Qubits (quantum computing) Time measurement
title	Ray-based framework for state identification in quantum dot devices
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