English

Faithful and secure distributed quantum sensing under general-coherent attacks

Quantum Physics 2025-05-06 v1 Mathematical Physics math.MP Optics

Abstract

Quantum metrology and cryptography can be combined in a distributed and/or remote sensing setting, where distant end-users with limited quantum capabilities can employ quantum states, transmitted by a quantum-powerful provider via a quantum network, to perform quantum-enhanced parameter estimation in a private fashion. Previous works on the subject have been limited by restricted assumptions on the capabilities of a potential eavesdropper and the use of abort-based protocols that prevent a simple practical realization. Here we introduce, theoretically analyze, and experimentally demonstrate single- and two-way protocols for distributed sensing combining several unique and desirable features: (i) a safety-threshold mechanism that allows the protocol to proceed in low-noise cases and quantifying the potential tampering with respect to the ideal estimation procedure, effectively paving the way for wide-spread practical realizations; (ii) equivalence of entanglement-based and mutually-unbiased-bases-based formulations; (iii) robustness against collective attacks via a LOCC-de-Finetti theorem, for the first time to our knowledge. Finally, we demonstrate our protocols in a photonic-based implementation, observing that the possibility of guaranteeing a safety threshold may come at a significant price in terms of the estimation bias, potentially overestimating the effect of tampering in practical settings.

Keywords

Cite

@article{arxiv.2505.02620,
  title  = {Faithful and secure distributed quantum sensing under general-coherent attacks},
  author = {G. Bizzarri and M. Barbieri and M. Manrique and M. Parisi and F. Bruni and I. Gianani and M. Rosati},
  journal= {arXiv preprint arXiv:2505.02620},
  year   = {2025}
}

Comments

10+4 pages; 4 figures

R2 v1 2026-06-28T23:21:27.205Z