Saved in:
Bibliographic Details
Main Authors: Rossetti, Leonardo, Mancini, Stefano, Winter, Andreas, Schindler, Joseph
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.10058
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911203921494016
author Rossetti, Leonardo
Mancini, Stefano
Winter, Andreas
Schindler, Joseph
author_facet Rossetti, Leonardo
Mancini, Stefano
Winter, Andreas
Schindler, Joseph
contents The use of coarse graining to connect physical and information theoretic entropies has recently been given a precise formulation in terms of ``observational entropy'', describing entropy for observers with respect to a measurement. Here we consider observers with various locality restrictions, including local measurements (LO), measurements based on local operations with classical communication (LOCC), and separable measurements (SEP), with the idea that the ``entropy gap'' between the minimum locally measured observational entropy and the von Neumann entropy quantifies quantum correlations in a given state. After introducing entropy gaps for general classes of measurements and deriving their general properties, we specialize to LO, LOCC, SEP and other measurement classes related to the locality of subsystems. For those, we show that the entropy gap can be related to well-known measures of entanglement or non-classicality of the state (even though we point out that they are not entanglement monotones themselves). In particular, for bipartite pure states, all of the ``local'' entropy gaps reproduce the entanglement entropy, and for general multipartite states they are lower-bounded by the relative entropy of entanglement. The entropy gaps of the different measurement classes are ordered, and we show that in general (mixed and multipartite states) they are all different.
format Preprint
id arxiv_https___arxiv_org_abs_2510_10058
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Observational entropy of quantum correlations and entanglement
Rossetti, Leonardo
Mancini, Stefano
Winter, Andreas
Schindler, Joseph
Quantum Physics
The use of coarse graining to connect physical and information theoretic entropies has recently been given a precise formulation in terms of ``observational entropy'', describing entropy for observers with respect to a measurement. Here we consider observers with various locality restrictions, including local measurements (LO), measurements based on local operations with classical communication (LOCC), and separable measurements (SEP), with the idea that the ``entropy gap'' between the minimum locally measured observational entropy and the von Neumann entropy quantifies quantum correlations in a given state. After introducing entropy gaps for general classes of measurements and deriving their general properties, we specialize to LO, LOCC, SEP and other measurement classes related to the locality of subsystems. For those, we show that the entropy gap can be related to well-known measures of entanglement or non-classicality of the state (even though we point out that they are not entanglement monotones themselves). In particular, for bipartite pure states, all of the ``local'' entropy gaps reproduce the entanglement entropy, and for general multipartite states they are lower-bounded by the relative entropy of entanglement. The entropy gaps of the different measurement classes are ordered, and we show that in general (mixed and multipartite states) they are all different.
title Observational entropy of quantum correlations and entanglement
topic Quantum Physics
url https://arxiv.org/abs/2510.10058