Abstracts

Renyi relative entropies of quantum Gaussian states

Presenting Author: Kaushik Seshadreesan, University of Arizona
Contributing Author(s): Ludovico Lami and Mark M. Wilde

The quantum Rényi relative entropies play a prominent role in quantum information theory, finding applications in characterizing error exponents and strong converse exponents for quantum hypothesis testing and quantum communication theory. On a different thread, quantum Gaussian states have been intensely investigated theoretically, motivated by the fact that they are more readily accessible in the laboratory than are other, more exotic quantum states. In this talk, we discuss the derivation of formulas for the quantum Rényi relative entropies of quantum Gaussian states. We consider both the traditional (Petz) Rényi relative entropy as well as the more recent sandwiched Rényi relative entropy, finding formulas that are expressed solely in terms of the mean vectors and covariance matrices of the underlying quantum Gaussian states. Our development handles the hitherto elusive case for the Petz-Rényi relative entropy when the Rényi parameter is larger than one. Finally, we also derive a formula for the max-relative entropy of two quantum Gaussian states, and we discuss some applications of the formulas derived here.

Read this article online: https://arxiv.org/pdf/1706.09885.pdf

(Session 2 : Thursday from 11:30am-12:00pm)

 

SQuInT Chief Organizer
Akimasa Miyake, Assistant Professor
amiyake@unm.edu

SQuInT Co-Organizer
Mark M. Wilde, Assistant Professor LSU
mwilde@phys.lsu.edu

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Gloria Cordova
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505 277-1850

SQuInT Founder
Ivan Deutsch, Regents' Professor
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