Litcius/Paper detail

Quantum advantage in postselected metrology

David R. M. Arvidsson-Shukur, Nicole Yunger Halpern, Hugo V. Lepage, Aleksander A. Lasek, Crispin H. W. Barnes, Seth Lloyd

2020Nature Communications132 citationsDOIOpen Access PDF

Abstract

In every parameter-estimation experiment, the final measurement or the postprocessing incurs a cost. Postselection can improve the rate of Fisher information (the average information learned about an unknown parameter from a trial) to cost. We show that this improvement stems from the negativity of a particular quasiprobability distribution, a quantum extension of a probability distribution. In a classical theory, in which all observables commute, our quasiprobability distribution is real and nonnegative. In a quantum-mechanically noncommuting theory, nonclassicality manifests in negative or nonreal quasiprobabilities. Negative quasiprobabilities enable postselected experiments to outperform optimal postselection-free experiments: postselected quantum experiments can yield anomalously large information-cost rates. This advantage, we prove, is unrealizable in any classically commuting theory. Finally, we construct a preparation-and-postselection procedure that yields an arbitrarily large Fisher information. Our results establish the nonclassicality of a metrological advantage, leveraging our quasiprobability distribution as a mathematical tool.

Topics & Concepts

PostselectionObservableStatistical physicsQuantum metrologyProbability distributionFisher informationQuantumNegativity effectPhysicsMetrologyExtension (predicate logic)Quantum mechanicsComputer scienceQuantum entanglementMathematicsQuantum discordQuantum informationQuantum teleportationQuantum stateDistribution (mathematics)State (computer science)AlgorithmQuantum decoherenceQuantum information processingProbability and statisticsSpontaneous parametric down-conversionQuantum opticsQuantum technologyQuantum channelCoherent statesApplied mathematicsConstruct (python library)Nonclassical lightQuantum networkQuantum Mechanics and ApplicationsStatistical Mechanics and EntropyQuantum Information and Cryptography