Quantum state estimation when qubits are lost: A no-data-left-behind approach

Brian P. Williams; Pavel Lougovski

doi:10.1088/1367-2630/aa65de

Quantum state estimation when qubits are lost: A no-data-left-behind approach

Brian P. Williams, Pavel Lougovski

Quantum Communications and Networking

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

22 Scopus citations

Abstract

We present an approach to Bayesian mean estimation of quantum states using hyperspherical parametrization and an experiment-specific likelihood which allows utilization of all available data, even when qubits are lost. With this method, we report the first closed-form Bayesian mean estimate (BME) for the ideal single qubit. Due to computational constraints, we utilize numerical sampling to determine the BME for a photonic two-qubit experiment in which our novel analysis reduces burdens associated with experimental asymmetries and inefficiencies. This method can be applied to quantum states of any dimension and experimental complexity.

Original language	English
Article number	043003
Journal	New Journal of Physics
Volume	19
Issue number	4
DOIs	https://doi.org/10.1088/1367-2630/aa65de
State	Published - Apr 2017

Keywords

Bayesian
Monte Carlo
inference
quantum state estimation
qubit
slice sampling

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10.1088/1367-2630/aa65de

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title = "Quantum state estimation when qubits are lost: A no-data-left-behind approach",

abstract = "We present an approach to Bayesian mean estimation of quantum states using hyperspherical parametrization and an experiment-specific likelihood which allows utilization of all available data, even when qubits are lost. With this method, we report the first closed-form Bayesian mean estimate (BME) for the ideal single qubit. Due to computational constraints, we utilize numerical sampling to determine the BME for a photonic two-qubit experiment in which our novel analysis reduces burdens associated with experimental asymmetries and inefficiencies. This method can be applied to quantum states of any dimension and experimental complexity.",

keywords = "Bayesian, Monte Carlo, inference, quantum state estimation, qubit, slice sampling",

author = "Williams, \{Brian P.\} and Pavel Lougovski",

note = "Publisher Copyright: {\textcopyright} 2017 Not subject to copyright in the USA. Contribution of Oak Ridge National Laboratory.",

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T1 - Quantum state estimation when qubits are lost

T2 - A no-data-left-behind approach

AU - Williams, Brian P.

AU - Lougovski, Pavel

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N2 - We present an approach to Bayesian mean estimation of quantum states using hyperspherical parametrization and an experiment-specific likelihood which allows utilization of all available data, even when qubits are lost. With this method, we report the first closed-form Bayesian mean estimate (BME) for the ideal single qubit. Due to computational constraints, we utilize numerical sampling to determine the BME for a photonic two-qubit experiment in which our novel analysis reduces burdens associated with experimental asymmetries and inefficiencies. This method can be applied to quantum states of any dimension and experimental complexity.

AB - We present an approach to Bayesian mean estimation of quantum states using hyperspherical parametrization and an experiment-specific likelihood which allows utilization of all available data, even when qubits are lost. With this method, we report the first closed-form Bayesian mean estimate (BME) for the ideal single qubit. Due to computational constraints, we utilize numerical sampling to determine the BME for a photonic two-qubit experiment in which our novel analysis reduces burdens associated with experimental asymmetries and inefficiencies. This method can be applied to quantum states of any dimension and experimental complexity.

KW - Bayesian

KW - Monte Carlo

KW - inference

KW - quantum state estimation

KW - qubit

KW - slice sampling

UR - https://www.scopus.com/pages/publications/85018980587

U2 - 10.1088/1367-2630/aa65de

DO - 10.1088/1367-2630/aa65de

M3 - Article

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SN - 1367-2630

VL - 19

JO - New Journal of Physics

JF - New Journal of Physics

IS - 4

M1 - 043003

ER -

Quantum state estimation when qubits are lost: A no-data-left-behind approach

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Keywords

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