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Bayesian multiparameter quantum metrology with limited data

Jesús Rubio, Jacob Dunningham

2020Physical review. A/Physical review, A77 citationsDOIOpen Access PDF

Abstract

A longstanding problem in quantum metrology is how to extract as much information as possible in realistic scenarios with not only multiple unknown parameters, but also limited measurement data and some degree of prior information. Here we present a practical solution to this: We derive a Bayesian multi-parameter quantum bound, construct the optimal measurement when our bound can be saturated for a single shot, and consider experiments involving a repeated sequence of these measurements. Our method properly accounts for the number of measurements and the degree of prior information, and we illustrate our ideas with a qubit sensing network and a model for phase imaging, clarifying the nonasymptotic role of local and global schemes. Crucially, our technique is a powerful way of implementing quantum protocols in a wide range of practical scenarios that tools such as the Helstrom and Holevo Cram\'er-Rao bounds cannot normally access.

Topics & Concepts

Quantum metrologyMetrologyComputer scienceQuantumUpper and lower boundsQubitBayesian probabilityAlgorithmConstruct (python library)Degree (music)Range (aeronautics)Quantum informationTheoretical computer scienceStatistical physicsMathematicsQuantum networkStatisticsArtificial intelligencePhysicsQuantum mechanicsEngineeringAerospace engineeringAcousticsMathematical analysisProgramming languageQuantum Information and CryptographyQuantum Mechanics and ApplicationsQuantum Computing Algorithms and Architecture
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