Enhanced standoff sensing resolution using quantum illumination
Abstract
Loss and noise quickly destroy quantum entanglement. Nevertheless, recent work has shown that a quadrature-entangled light source can reap a substantial performance advantage over all classical-state sources of the same average transmitter power in scenarios whose loss and noise makes them entanglement breaking, standoff target-detection being an example. In this paper, we make a first step in extending this quantum illumination paradigm to the optical imaging domain, viz., to obtain better spatial resolution for standoff optical sensing. Our canonical imaging scenario---restricted, for simplicity, to one transverse dimension---is taken to be that of resolving one versus two closely-spaced in-phase specular point targets. We show that an entangled-state transmitter, which uses continuous-wave-pumped spontaneous parametric downconversion (SPDC), achieves an error-probability exponent that exceeds that of all classical-state transmitters of the same average power. Using these error-exponent results, we find the ultimate spatial-resolution limits for coherent-state and SPDC imaging systems that use their respective quantum-optimal receivers, thus quantifying the latter's spatial-resolution advantage over the former. We also propose a structured optical receiver that is ideally capable of harnessing 3 dB (of the full 6 dB) gain in the error-probability exponent achievable by the SPDC transmitter and its quantum-optimal receiver.
Cite
@article{arxiv.1012.2548,
title = {Enhanced standoff sensing resolution using quantum illumination},
author = {Saikat Guha and Jeffrey H. Shapiro},
journal= {arXiv preprint arXiv:1012.2548},
year = {2015}
}
Comments
This 4-page article is based on a contributed talk presented at the Tenth International Conference on Quantum Communication, Measurement and Computation (QCMC) 2010, in Brisbane, Australia (http://qcmc2010.org/). This article has been submitted for the proceedings volume of QCMC 2010. After it is published, it will be available at http://proceedings.aip.org/