Tackling Sampling Noise in Physical Systems for Machine Learning Applications: Fundamental Limits and Eigentasks

Fangjun Hu; Gerasimos Angelatos; Saeed A. Khan; Marti Vives; Esin Türeci; Leon Bello; Graham E. Rowlands; Guilhem J. Ribeill; Hakan E. Türeci

doi:10.1103/PhysRevX.13.041020

Tackling Sampling Noise in Physical Systems for Machine Learning Applications: Fundamental Limits and Eigentasks

Fangjun Hu
, Gerasimos Angelatos
, Saeed A. Khan
, Marti Vives
, Esin Türeci
, Leon Bello
, Graham E. Rowlands
, Guilhem J. Ribeill
, Hakan E. Türeci

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

The expressive capacity of physical systems employed for learning is limited by the unavoidable presence of noise in their extracted outputs. Though present in physical systems across both the classical and quantum regimes, the precise impact of noise on learning remains poorly understood. Focusing on supervised learning, we present a mathematical framework for evaluating the resolvable expressive capacity (REC) of general physical systems under finite sampling noise and provide a methodology for extracting its extrema, the eigentasks. Eigentasks are a native set of functions that a given physical system can approximate with minimal error. We show that the REC of a quantum system is limited by the fundamental theory of quantum measurement and obtain a tight upper bound for the REC of any finitely sampled physical system. We then provide empirical evidence that extracting low-noise eigentasks can lead to improved performance for machine learning tasks such as classification, displaying robustness to overfitting. We present analyses suggesting that correlations in the measured quantum system enhance learning capacity by reducing noise in eigentasks. The applicability of these results in practice is demonstrated with experiments on superconducting quantum processors. Our findings have broad implications for quantum machine learning and sensing applications.

Original language	English
Article number	041020
Journal	Physical Review X
Volume	13
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevX.13.041020
State	Published - Oct 2023
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2023 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the "https://creativecommons.org/licenses/by/4.0/"Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

Funding

We express our sincere gratitude to the anonymous reviewers for their invaluable guidance, which significantly contributed to the refinement and enhancement of the final manuscript. We thank Ronen Eldan, Fatih Dinç, Daniel Gauthier, Michael Hatridge, Benjamin Lienhard, Peter McMachon, Sridhar Prabhu, Shyam Shankar, Francesco Tacchino, Logan Wright, and Xun Gao for stimulating discussions about the work that went into this manuscript. This research was developed with funding from the DARPA Contract No. HR00112190072, AFOSR Grant No. FA9550-20-1-0177, and AFOSR MURI Grant No. FA9550-22-1-0203. The views, opinions, and findings expressed are solely the authors’ and not the U.S. government’s.

Funders	Funder number
Air Force Office of Scientific Research	FA9550-20-1-0177, FA9550-22-1-0203
Defense Advanced Research Projects Agency	HR00112190072

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10.1103/PhysRevX.13.041020

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title = "Tackling Sampling Noise in Physical Systems for Machine Learning Applications: Fundamental Limits and Eigentasks",

abstract = "The expressive capacity of physical systems employed for learning is limited by the unavoidable presence of noise in their extracted outputs. Though present in physical systems across both the classical and quantum regimes, the precise impact of noise on learning remains poorly understood. Focusing on supervised learning, we present a mathematical framework for evaluating the resolvable expressive capacity (REC) of general physical systems under finite sampling noise and provide a methodology for extracting its extrema, the eigentasks. Eigentasks are a native set of functions that a given physical system can approximate with minimal error. We show that the REC of a quantum system is limited by the fundamental theory of quantum measurement and obtain a tight upper bound for the REC of any finitely sampled physical system. We then provide empirical evidence that extracting low-noise eigentasks can lead to improved performance for machine learning tasks such as classification, displaying robustness to overfitting. We present analyses suggesting that correlations in the measured quantum system enhance learning capacity by reducing noise in eigentasks. The applicability of these results in practice is demonstrated with experiments on superconducting quantum processors. Our findings have broad implications for quantum machine learning and sensing applications.",

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Tackling Sampling Noise in Physical Systems for Machine Learning Applications: Fundamental Limits and Eigentasks

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