Quantum Maximal Correlation for Gaussian States
- URL: http://arxiv.org/abs/2303.07155v1
- Date: Mon, 13 Mar 2023 14:29:03 GMT
- Title: Quantum Maximal Correlation for Gaussian States
- Authors: Salman Beigi, Saleh Rahimi-Keshari
- Abstract summary: We compute the quantum maximal correlation for bipartite Gaussian states of continuous-variable systems.
We show that the required optimization for computing the quantum maximal correlation of Gaussian states can be restricted to local operators that are linear in terms of phase-space quadrature operators.
- Score: 2.9443230571766845
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We compute the quantum maximal correlation for bipartite Gaussian states of
continuous-variable systems. Quantum maximal correlation is a measure of
correlation with the monotonicity and tensorization properties that can be used
to study whether an arbitrary number of copies of a resource state can be
locally transformed into a target state without classical communication, known
as the local state transformation problem. We show that the required
optimization for computing the quantum maximal correlation of Gaussian states
can be restricted to local operators that are linear in terms of phase-space
quadrature operators. This allows us to derive a closed-form expression for the
quantum maximal correlation in terms of the covariance matrix of Gaussian
states. Moreover, we define Gaussian maximal correlation based on considering
the class of local hermitian operators that are linear in terms of phase-space
quadrature operators associated with local homodyne measurements. This measure
satisfies the tensorization property and can be used for the Gaussian version
of the local state transformation problem when both resource and target states
are Gaussian. We also generalize these measures to the multipartite case.
Specifically, we define the quantum maximal correlation ribbon and then
characterize it for multipartite Gaussian states.
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