Provably superior accuracy in quantum stochastic modeling

Chengran Yang; Andrew J. P. Garner; Feiyang Liu; Nora Tischler; Jayne Thompson; Man-Hong Yung; Mile Gu; Oscar Dahlsten

doi:10.1103/PhysRevA.108.022411

Provably superior accuracy in quantum stochastic modeling

Chengran Yang^*
, Andrew J. P. Garner
, Feiyang Liu
, Nora Tischler
, Jayne Thompson
, Man-Hong Yung
, Mile Gu^*
, Oscar Dahlsten^*

^*Corresponding author for this work

Department of Physics

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

3 Citations (Scopus)

93 Downloads (CityUHK Scholars)

Abstract

In the design of stochastic models, there is a constant trade-off between model complexity and accuracy. Here we prove that quantum models enable a more favorable trade-off. We present a technique for identifying fundamental upper bounds on the predictive accuracy of dimensionality-constrained classical models. We identify quantum models that surpass this bound by creating an algorithm that learns quantum models given time-series data. We demonstrate that this quantum accuracy advantage is attainable in a present-day noisy quantum device. These results illustrate the immediate relevance of quantum technologies to time-series analysis and offer an instance where their resulting accuracy advantage can be provably established. © 2023 American Physical Society.

Original language	English
Article number	022411
Journal	Physical Review A
Volume	108
Issue number	2
Online published	10 Aug 2023
DOIs	https://doi.org/10.1103/PhysRevA.108.022411
Publication status	Published - Aug 2023

Publisher's Copyright Statement

COPYRIGHT TERMS OF DEPOSITED FINAL PUBLISHED VERSION FILE: Yang, C., Garner, A. J. P., Liu, F., Tischler, N., Thompson, J., Yung, M-H., Gu, M., & Dahlsten, O. (2023). Provably superior accuracy in quantum stochastic modeling. Physical Review A, 108(2), Article 022411. https://doi.org/10.1103/PhysRevA.108.022411. The copyright of this article is owned by American Physical Society.

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title = "Provably superior accuracy in quantum stochastic modeling",

abstract = "In the design of stochastic models, there is a constant trade-off between model complexity and accuracy. Here we prove that quantum models enable a more favorable trade-off. We present a technique for identifying fundamental upper bounds on the predictive accuracy of dimensionality-constrained classical models. We identify quantum models that surpass this bound by creating an algorithm that learns quantum models given time-series data. We demonstrate that this quantum accuracy advantage is attainable in a present-day noisy quantum device. These results illustrate the immediate relevance of quantum technologies to time-series analysis and offer an instance where their resulting accuracy advantage can be provably established. {\textcopyright} 2023 American Physical Society.",

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AU - Garner, Andrew J. P.

AU - Liu, Feiyang

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AU - Thompson, Jayne

AU - Yung, Man-Hong

AU - Gu, Mile

AU - Dahlsten, Oscar

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N2 - In the design of stochastic models, there is a constant trade-off between model complexity and accuracy. Here we prove that quantum models enable a more favorable trade-off. We present a technique for identifying fundamental upper bounds on the predictive accuracy of dimensionality-constrained classical models. We identify quantum models that surpass this bound by creating an algorithm that learns quantum models given time-series data. We demonstrate that this quantum accuracy advantage is attainable in a present-day noisy quantum device. These results illustrate the immediate relevance of quantum technologies to time-series analysis and offer an instance where their resulting accuracy advantage can be provably established. © 2023 American Physical Society.

AB - In the design of stochastic models, there is a constant trade-off between model complexity and accuracy. Here we prove that quantum models enable a more favorable trade-off. We present a technique for identifying fundamental upper bounds on the predictive accuracy of dimensionality-constrained classical models. We identify quantum models that surpass this bound by creating an algorithm that learns quantum models given time-series data. We demonstrate that this quantum accuracy advantage is attainable in a present-day noisy quantum device. These results illustrate the immediate relevance of quantum technologies to time-series analysis and offer an instance where their resulting accuracy advantage can be provably established. © 2023 American Physical Society.

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M3 - RGC 21 - Publication in refereed journal

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VL - 108

JO - Physical Review A

JF - Physical Review A

IS - 2

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Provably superior accuracy in quantum stochastic modeling

Abstract

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