Experimental quantum Hamiltonian learning

Jianwei Wang; Stefano Paesani; Raffaele Santagati; Sebastian Knauer; Antonio A. Gentile; Nathan Wiebe; Maurangelo Petruzzella; Jeremy L. O’Brien; John G. Rarity; Anthony Laing; Mark G. Thompson

doi:10.1038/nphys4074

Experimental quantum Hamiltonian learning

Jianwei Wang^*, Stefano Paesani, Raffaele Santagati, Sebastian Knauer, Antonio A. Gentile, Nathan Wiebe, Maurangelo Petruzzella, Jeremy L. O’Brien, John G. Rarity, Anthony Laing, Mark G. Thompson

^*Corresponding author for this work

Research output: Contribution to journal › Letter (Academic Journal) › peer-review

127 Citations (Scopus)

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Abstract

The efficient characterization of quantum systems, the verification of the operations of quantum devices and the validation of underpinning physical models, are central challenges for quantum technologies and fundamental physics. The computational cost of such studies could be improved by machine learning enhanced by quantum simulators. Here we interface two different quantum systems through a classical channel—a silicon-photonics quantum simulator and an electron spin in a diamond nitrogen–vacancy centre—and use the former to learn the Hamiltonian of the latter via Bayesian inference. We learn the salient Hamiltonian parameter with an uncertainty of approximately 10^-5. Furthermore, an observed saturation in the learning algorithm suggests deficiencies in the underlying Hamiltonian model, which we exploit to further improve the model. We implement an interactive version of the protocol and experimentally show its ability to characterize the operation of the quantum photonic device.

Original language	English
Pages (from-to)	551-555
Number of pages	5
Journal	Nature Physics
Volume	13
Issue number	6
Early online date	13 Mar 2017
DOIs	https://doi.org/10.1038/nphys4074
Publication status	Published - 1 Jun 2017

Structured keywords

Bristol Quantum Information Institute
QETLabs

Keywords

Quantum information processing
Quantum optics
silicon photonics
nv centers

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10.1038/nphys4074

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title = "Experimental quantum Hamiltonian learning",

abstract = "The efficient characterization of quantum systems, the verification of the operations of quantum devices and the validation of underpinning physical models, are central challenges for quantum technologies and fundamental physics. The computational cost of such studies could be improved by machine learning enhanced by quantum simulators. Here we interface two different quantum systems through a classical channel—a silicon-photonics quantum simulator and an electron spin in a diamond nitrogen–vacancy centre—and use the former to learn the Hamiltonian of the latter via Bayesian inference. We learn the salient Hamiltonian parameter with an uncertainty of approximately 10-5. Furthermore, an observed saturation in the learning algorithm suggests deficiencies in the underlying Hamiltonian model, which we exploit to further improve the model. We implement an interactive version of the protocol and experimentally show its ability to characterize the operation of the quantum photonic device.",

keywords = "Quantum information processing, Quantum optics, silicon photonics, nv centers",

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AU - Wang, Jianwei

AU - Paesani, Stefano

AU - Santagati, Raffaele

AU - Knauer, Sebastian

AU - Gentile, Antonio A.

AU - Wiebe, Nathan

AU - Petruzzella, Maurangelo

AU - O’Brien, Jeremy L.

AU - Rarity, John G.

AU - Laing, Anthony

AU - Thompson, Mark G.

PY - 2017/6/1

Y1 - 2017/6/1

N2 - The efficient characterization of quantum systems, the verification of the operations of quantum devices and the validation of underpinning physical models, are central challenges for quantum technologies and fundamental physics. The computational cost of such studies could be improved by machine learning enhanced by quantum simulators. Here we interface two different quantum systems through a classical channel—a silicon-photonics quantum simulator and an electron spin in a diamond nitrogen–vacancy centre—and use the former to learn the Hamiltonian of the latter via Bayesian inference. We learn the salient Hamiltonian parameter with an uncertainty of approximately 10-5. Furthermore, an observed saturation in the learning algorithm suggests deficiencies in the underlying Hamiltonian model, which we exploit to further improve the model. We implement an interactive version of the protocol and experimentally show its ability to characterize the operation of the quantum photonic device.

AB - The efficient characterization of quantum systems, the verification of the operations of quantum devices and the validation of underpinning physical models, are central challenges for quantum technologies and fundamental physics. The computational cost of such studies could be improved by machine learning enhanced by quantum simulators. Here we interface two different quantum systems through a classical channel—a silicon-photonics quantum simulator and an electron spin in a diamond nitrogen–vacancy centre—and use the former to learn the Hamiltonian of the latter via Bayesian inference. We learn the salient Hamiltonian parameter with an uncertainty of approximately 10-5. Furthermore, an observed saturation in the learning algorithm suggests deficiencies in the underlying Hamiltonian model, which we exploit to further improve the model. We implement an interactive version of the protocol and experimentally show its ability to characterize the operation of the quantum photonic device.

KW - Quantum information processing

KW - Quantum optics

KW - silicon photonics

KW - nv centers

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VL - 13

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EP - 555

JO - Nature Physics

JF - Nature Physics

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Experimental quantum Hamiltonian learning

Abstract

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Keywords

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A practical quantum simulator: simulating molecular vibrations with photons. ECF

Two level systems for scalable quantum processors

QComms: UK Quantum Technology Hub for Quantum Communication Technologies (via York)

Operating practical quantum devices in the pre-threshold regime

Professor Anthony Laing

Cite this

Experimental quantum Hamiltonian learning

Abstract

Structured keywords

Keywords

Access to Document

Handle.net

Other files and links

Fingerprint

Projects

A practical quantum simulator: simulating molecular vibrations with photons. ECF

Two level systems for scalable quantum processors

QComms: UK Quantum Technology Hub for Quantum Communication Technologies (via York)

Student theses

Operating practical quantum devices in the pre-threshold regime

Profiles

Professor Anthony Laing

Cite this