English

Covert Optical Communication

Information Theory 2016-08-31 v4 math.IT Quantum Physics

Abstract

Encryption prevents unauthorized decoding, but does not ensure stealth---a security demand that a mere presence of a message be undetectable. We characterize the ultimate limit of covert communication that is secure against the most powerful physically-permissible adversary. We show that, although it is impossible over a pure-loss channel, covert communication is attainable in the presence of any excess noise, such as a 300300K thermal blackbody. In this case, O(n)\mathcal{O}(\sqrt{n}) bits can be transmitted reliably and covertly in nn optical modes using standard optical communication equipment. The all-powerful adversary may intercept all transmitted photons not received by the intended receiver, and employ arbitrary quantum memory and measurements. Conversely, we show that this square root scaling cannot be outperformed. We corroborate our theory in a proof-of-concept experiment. We believe that our findings will enable practical realizations of covert communication and sensing, both for point-to-point and networked scenarios.

Keywords

Cite

@article{arxiv.1404.7347,
  title  = {Covert Optical Communication},
  author = {Boulat A. Bash and Andrei H. Gheorghe and Monika Patel and Jonathan Habif and Dennis Goeckel and Don Towsley and Saikat Guha},
  journal= {arXiv preprint arXiv:1404.7347},
  year   = {2016}
}

Comments

v4: improved organization and figures, no changes to the results; v3: significant changes, included new theoretical results as well as re-organized; v2: updated figure 3 with theoretical channel capacity curves + minor fixes, no changes to experiments or other main results

R2 v1 2026-06-22T04:01:45.275Z