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Measuring relational information between quantum states, and applications

Michał Oszmaniec, Daniel J. Brod, Ernesto F. Galvão

2024New Journal of Physics30 citationsDOIOpen Access PDF

Abstract

Abstract The geometrical arrangement of a set of quantum states can be completely characterized using relational information only. This information is encoded in the pairwise state overlaps, as well as in Bargmann invariants of higher degree written as traces of products of density matrices. We describe how to measure Bargmann invariants using suitable generalizations of the SWAP test. This allows for a complete and robust characterization of the projective-unitary invariant properties of any set of pure or mixed states. As applications, we describe basis-independent tests for linear independence, coherence, and imaginarity. We also show that Bargmann invariants can be used to characterize multi-photon indistinguishability.

Topics & Concepts

PhysicsUnitary stateInvariant (physics)Coherence (philosophical gambling strategy)QuantumPure mathematicsCharacterization (materials science)Quantum stateIndependence (probability theory)Quantum entanglementTheoretical physicsSet (abstract data type)Quantum informationMeasure (data warehouse)Pairwise comparisonProjective testQuantum mechanicsStatistical physicsMathematicsData miningComputer sciencePolitical scienceOpticsProgramming languageLawStatisticsQuantum Information and CryptographyQuantum Computing Algorithms and ArchitectureQuantum Mechanics and Applications
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