Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information

Hany Ali; Jorge Marques; Ophelia Crawford; Joonas Majaniemi; Marc Serra-Peraltal; David Byfield; Boris Varbanov; Barbara M. Terhal; Leonardo Dicarlo; Earl T. Campbell

doi:10.1109/QCE60285.2024.10316

Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information

Hany Ali, Jorge Marques, Ophelia Crawford, Joonas Majaniemi, Marc Serra-Peraltal, David Byfield, Boris Varbanov, Barbara M. Terhal, Leonardo Dicarlo, Earl T. Campbell

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

Abstract

Quantum error correction allows for quantum information to be preserved using logical qubits, which are subject to lower error rates than their constituent physical qubits. The degree of error suppression depends on the choice of error correcting code and distance, the underlying physical error rate, and the accuracy of the decoder. While traditional decoders utilise a binary (hard) syndrome, recent work shows that additional (soft) information captured during qubit readout can be effectively utilised to improve decoding accuracy. In this work, we present experimental results from a distance-three surface code implemented on transmon qubits, where we perform Z-stabiliser measurements to protect the state of the logical qubit against bit-flip errors. We initialise the logical qubit in one of 16 possible computational states representing the logical zero state, and perform repeated stabiliser checks over a variable number of rounds to preserve the state over time. We compare the decoding performance for a hard minimum-weight perfect matching decoder against a soft variant where rich measurement information is incorporated, and demonstrate an improved logical fidelity. Additionally, we employ a recurrent neural network decoder with both soft and hard variants and observe improved performance when soft information is used. The general nature of soft information makes it widely applicable to different physical qubit platforms, where it can be leveraged to shorten measurement times and improve the logical fidelity in quantum error correction experiments. Pre-print available at arXiv:2403.00706.

Original language	English
Title of host publication	Workshops Program, Posters Program, Panels Program and Tutorials Program
Editors	Candace Culhane, Greg T. Byrd, Hausi Muller, Yuri Alexeev, Yuri Alexeev, Sarah Sheldon
Publisher	IEEE
Pages	382-383
Number of pages	2
ISBN (Electronic)	9798331541378
DOIs	https://doi.org/10.1109/QCE60285.2024.10316
Publication status	Published - 2024
Event	5th IEEE International Conference on Quantum Computing and Engineering, QCE 2024 - Montreal, Canada Duration: 15 Sept 2024 → 20 Sept 2024

Publication series

Name	Proceedings - IEEE Quantum Week 2024, QCE 2024
Volume	2

Conference

Conference	5th IEEE International Conference on Quantum Computing and Engineering, QCE 2024
Country/Territory	Canada
City	Montreal
Period	15/09/24 → 20/09/24

Bibliographical note

Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care
Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.

Keywords

decoding
Quantum error correction
soft information
superconducting qubits

Access to Document

10.1109/QCE60285.2024.10316

Cite this

Ali, H., Marques, J., Crawford, O., Majaniemi, J., Serra-Peraltal, M., Byfield, D., Varbanov, B., Terhal, B. M., Dicarlo, L., & Campbell, E. T. (2024). Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information. In C. Culhane, G. T. Byrd, H. Muller, Y. Alexeev, Y. Alexeev, & S. Sheldon (Eds.), Workshops Program, Posters Program, Panels Program and Tutorials Program (pp. 382-383). (Proceedings - IEEE Quantum Week 2024, QCE 2024; Vol. 2). IEEE. https://doi.org/10.1109/QCE60285.2024.10316

Ali, Hany ; Marques, Jorge ; Crawford, Ophelia et al. / Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information. Workshops Program, Posters Program, Panels Program and Tutorials Program. editor / Candace Culhane ; Greg T. Byrd ; Hausi Muller ; Yuri Alexeev ; Yuri Alexeev ; Sarah Sheldon. IEEE, 2024. pp. 382-383 (Proceedings - IEEE Quantum Week 2024, QCE 2024).

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title = "Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information",

abstract = "Quantum error correction allows for quantum information to be preserved using logical qubits, which are subject to lower error rates than their constituent physical qubits. The degree of error suppression depends on the choice of error correcting code and distance, the underlying physical error rate, and the accuracy of the decoder. While traditional decoders utilise a binary (hard) syndrome, recent work shows that additional (soft) information captured during qubit readout can be effectively utilised to improve decoding accuracy. In this work, we present experimental results from a distance-three surface code implemented on transmon qubits, where we perform Z-stabiliser measurements to protect the state of the logical qubit against bit-flip errors. We initialise the logical qubit in one of 16 possible computational states representing the logical zero state, and perform repeated stabiliser checks over a variable number of rounds to preserve the state over time. We compare the decoding performance for a hard minimum-weight perfect matching decoder against a soft variant where rich measurement information is incorporated, and demonstrate an improved logical fidelity. Additionally, we employ a recurrent neural network decoder with both soft and hard variants and observe improved performance when soft information is used. The general nature of soft information makes it widely applicable to different physical qubit platforms, where it can be leveraged to shorten measurement times and improve the logical fidelity in quantum error correction experiments. Pre-print available at arXiv:2403.00706.",

keywords = "decoding, Quantum error correction, soft information, superconducting qubits",

author = "Hany Ali and Jorge Marques and Ophelia Crawford and Joonas Majaniemi and Marc Serra-Peraltal and David Byfield and Boris Varbanov and Terhal, {Barbara M.} and Leonardo Dicarlo and Campbell, {Earl T.}",

note = "Green Open Access added to TU Delft Institutional Repository {\textquoteleft}You share, we take care!{\textquoteright} – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.; 5th IEEE International Conference on Quantum Computing and Engineering, QCE 2024 ; Conference date: 15-09-2024 Through 20-09-2024",

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doi = "10.1109/QCE60285.2024.10316",

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Ali, H, Marques, J, Crawford, O, Majaniemi, J, Serra-Peraltal, M, Byfield, D, Varbanov, B, Terhal, BM , Dicarlo, L & Campbell, ET 2024, Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information. in C Culhane, GT Byrd, H Muller, Y Alexeev, Y Alexeev & S Sheldon (eds), Workshops Program, Posters Program, Panels Program and Tutorials Program. Proceedings - IEEE Quantum Week 2024, QCE 2024, vol. 2, IEEE, pp. 382-383, 5th IEEE International Conference on Quantum Computing and Engineering, QCE 2024, Montreal, Canada, 15/09/24. https://doi.org/10.1109/QCE60285.2024.10316

Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information. / Ali, Hany; Marques, Jorge; Crawford, Ophelia et al.
Workshops Program, Posters Program, Panels Program and Tutorials Program. ed. / Candace Culhane; Greg T. Byrd; Hausi Muller; Yuri Alexeev; Yuri Alexeev; Sarah Sheldon. IEEE, 2024. p. 382-383 (Proceedings - IEEE Quantum Week 2024, QCE 2024; Vol. 2).

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

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AB - Quantum error correction allows for quantum information to be preserved using logical qubits, which are subject to lower error rates than their constituent physical qubits. The degree of error suppression depends on the choice of error correcting code and distance, the underlying physical error rate, and the accuracy of the decoder. While traditional decoders utilise a binary (hard) syndrome, recent work shows that additional (soft) information captured during qubit readout can be effectively utilised to improve decoding accuracy. In this work, we present experimental results from a distance-three surface code implemented on transmon qubits, where we perform Z-stabiliser measurements to protect the state of the logical qubit against bit-flip errors. We initialise the logical qubit in one of 16 possible computational states representing the logical zero state, and perform repeated stabiliser checks over a variable number of rounds to preserve the state over time. We compare the decoding performance for a hard minimum-weight perfect matching decoder against a soft variant where rich measurement information is incorporated, and demonstrate an improved logical fidelity. Additionally, we employ a recurrent neural network decoder with both soft and hard variants and observe improved performance when soft information is used. The general nature of soft information makes it widely applicable to different physical qubit platforms, where it can be leveraged to shorten measurement times and improve the logical fidelity in quantum error correction experiments. Pre-print available at arXiv:2403.00706.

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Ali H, Marques J, Crawford O, Majaniemi J, Serra-Peraltal M, Byfield D et al. Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information. In Culhane C, Byrd GT, Muller H, Alexeev Y, Alexeev Y, Sheldon S, editors, Workshops Program, Posters Program, Panels Program and Tutorials Program. IEEE. 2024. p. 382-383. (Proceedings - IEEE Quantum Week 2024, QCE 2024). doi: 10.1109/QCE60285.2024.10316

Reducing the Error Rate of a Superconducting Logical Qubit using Analog Readout Information

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