Machine learning for continuous quantum error correction on superconducting qubits

Ian Convy; Haoran Liao; Song Zhang; Sahil Patel; William P Livingston; Ho Nam Nguyen; Irfan Siddiqi; K Birgitta Whaley

doi:10.1088/1367-2630/ac66f9

New Journal of Physics (Jan 2022)

Machine learning for continuous quantum error correction on superconducting qubits

Ian Convy,
Haoran Liao,
Song Zhang,
Sahil Patel,
William P Livingston,
Ho Nam Nguyen,
Irfan Siddiqi,
K Birgitta Whaley

Affiliations

Ian Convy: ORCiD; Department of Chemistry, University of California , Berkeley, CA 94720, United States of America; Berkeley Quantum Information and Computation Center, University of California , Berkeley, CA 94720, United States of America; Challenge Institute for Quantum Computation, University of California , Berkeley, CA 94720, United States of America
Haoran Liao: ORCiD; Berkeley Quantum Information and Computation Center, University of California , Berkeley, CA 94720, United States of America; Challenge Institute for Quantum Computation, University of California , Berkeley, CA 94720, United States of America; Department of Physics, University of California , Berkeley, CA 94720, United States of America
Song Zhang: Berkeley Quantum Information and Computation Center, University of California , Berkeley, CA 94720, United States of America; Challenge Institute for Quantum Computation, University of California , Berkeley, CA 94720, United States of America; Department of Physics, University of California , Berkeley, CA 94720, United States of America
Sahil Patel: Berkeley Quantum Information and Computation Center, University of California , Berkeley, CA 94720, United States of America; Challenge Institute for Quantum Computation, University of California , Berkeley, CA 94720, United States of America; Department of Physics, University of California , Berkeley, CA 94720, United States of America; Department of Computer Science, University of California , Berkeley, CA 94720, United States of America
William P Livingston: Department of Physics, University of California , Berkeley, CA 94720, United States of America; Center for Quantum Coherent Science, University of California , Berkeley, CA 94720, United States of America
Ho Nam Nguyen: Berkeley Quantum Information and Computation Center, University of California , Berkeley, CA 94720, United States of America; Challenge Institute for Quantum Computation, University of California , Berkeley, CA 94720, United States of America; Department of Physics, University of California , Berkeley, CA 94720, United States of America
Irfan Siddiqi: Department of Physics, University of California , Berkeley, CA 94720, United States of America; Department of Computer Science, University of California , Berkeley, CA 94720, United States of America
K Birgitta Whaley: ORCiD; Department of Chemistry, University of California , Berkeley, CA 94720, United States of America; Berkeley Quantum Information and Computation Center, University of California , Berkeley, CA 94720, United States of America; Challenge Institute for Quantum Computation, University of California , Berkeley, CA 94720, United States of America; Center for Quantum Coherent Science, University of California , Berkeley, CA 94720, United States of America

DOI: https://doi.org/10.1088/1367-2630/ac66f9
Journal volume & issue: Vol. 24, no. 6
p. 063019

Abstract

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Continuous quantum error correction has been found to have certain advantages over discrete quantum error correction, such as a reduction in hardware resources and the elimination of error mechanisms introduced by having entangling gates and ancilla qubits. We propose a machine learning algorithm for continuous quantum error correction that is based on the use of a recurrent neural network to identify bit-flip errors from continuous noisy syndrome measurements. The algorithm is designed to operate on measurement signals deviating from the ideal behavior in which the mean value corresponds to a code syndrome value and the measurement has white noise. We analyze continuous measurements taken from a superconducting architecture using three transmon qubits to identify three significant practical examples of non-ideal behavior, namely auto-correlation at temporal short lags, transient syndrome dynamics after each bit-flip, and drift in the steady-state syndrome values over the course of many experiments. Based on these real-world imperfections, we generate synthetic measurement signals from which to train the recurrent neural network, and then test its proficiency when implementing active error correction, comparing this with a traditional double threshold scheme and a discrete Bayesian classifier. The results show that our machine learning protocol is able to outperform the double threshold protocol across all tests, achieving a final state fidelity comparable to the discrete Bayesian classifier.

Published in New Journal of Physics

ISSN: 1367-2630 (Online)
Publisher: IOP Publishing
Country of publisher: United Kingdom
LCC subjects: Science: Physics
Website: https://iopscience.iop.org/journal/1367-2630

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