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Optimal Distributed quantum sensing using Gaussian states

Quantum Physics 2020-04-14 v2

Abstract

We find and investigate the optimal scheme of quantum distributed Gaussian sensing for estimation of the average of independent phase shifts. We show that the ultimate sensitivity is achievable by using an entangled symmetric Gaussian state, which can be generated using a single-mode squeezed vacuum state, a beam-splitter network, and homodyne detection on each output mode in the absence of photon loss. Interestingly, the maximal entanglement of a symmetric Gaussian state is not optimal although the presence of entanglement is advantageous as compared to the case using a product symmetric Gaussian state. It is also demonstrated that when loss occurs, homodyne detection and other types of Gaussian measurements compete for better sensitivity, depending on the amount of loss and properties of a probe state. None of them provide the ultimate sensitivity, indicating that non-Gaussian measurements are required for optimality in lossy cases. Our general results obtained through a full-analytical investigation will offer important perspectives to the future theoretical and experimental study for quantum distributed Gaussian sensing.

Keywords

Cite

@article{arxiv.1910.00823,
  title  = {Optimal Distributed quantum sensing using Gaussian states},
  author = {Changhun Oh and Changhyoup Lee and Seok Hyung Lie and Hyunseok Jeong},
  journal= {arXiv preprint arXiv:1910.00823},
  year   = {2020}
}

Comments

10 pages, 5 figures; final version accepted in Physical Review Research

R2 v1 2026-06-23T11:32:29.264Z