English

Continuous-variable quantum digital signatures that can withstand coherent attacks

Quantum Physics 2024-11-25 v2

Abstract

Quantum digital signatures (QDSs), which utilize correlated bit strings among sender and recipients, guarantee the authenticity, integrity, and nonrepudiation of classical messages based on quantum laws. Continuous-variable (CV) quantum protocol with heterodyne and homodyne measurement has obvious advantages of low-cost implementation and easy wavelength division multiplexing. However, security analyses in previous researches are limited to the proof against collective attacks in finite-size scenarios. Moreover, existing multibit CV QDS schemes have primarily focused on adapting single-bit protocols for simplicity of security proof, often sacrificing signature efficiency. Here, we introduce a CV QDS protocol designed to withstand general coherent attacks through the use of a cutting-edge fidelity test function, while achieving high signature efficiency by employing a refined one-time universal hashing signing technique. Our protocol is proved to be robust against finite-size effects and excess noise in quantum channels. In simulation, results demonstrate a significant reduction of eight orders of magnitude in signature length for a megabit message signing task compared with existing CV QDS protocols and this advantage expands as the message size grows. Our work offers a solution with enhanced security and efficiency, paving the way for large-scale deployment of CV QDSs in future quantum networks.

Keywords

Cite

@article{arxiv.2407.03609,
  title  = {Continuous-variable quantum digital signatures that can withstand coherent attacks},
  author = {Yi-Fan Zhang and Wen-Bo Liu and Bing-Hong Li and Hua-Lei Yin and Zeng-Bing Chen},
  journal= {arXiv preprint arXiv:2407.03609},
  year   = {2024}
}

Comments

19 pages, 8 figures

R2 v1 2026-06-28T17:28:43.487Z