Quantum Sensor Miniaturization

Author

Gilbert, G. ; Hamrick, M. ; Weinstein, Y.S. ; Pappas, S.P. ; Donadio, A.

Author_Institution

MITRE, Eatontown

Volume

19

Issue

22

fYear

2007

Firstpage

1798

Lastpage

1800

Abstract

The classical bound on image resolution defined by the Rayleigh limit can be beaten by exploiting the properties of quantum mechanical entanglement. If entangled photons are used as signal states, the best possible resolution is instead given by the Heisenberg limit, an improvement proportional to the number of entangled photons in the signal. In this paper, we present a novel application of entanglement by showing that the resolution obtained by an imaging system utilizing separable photons can be achieved by an imaging system making use of entangled photons, but with the advantage of a smaller aperture, thus resulting in a smaller and lighter system. This can be especially valuable in satellite imaging where weight and size play a vital role.

Keywords

image resolution; image sensors; quantum entanglement; quantum interference phenomena; quantum optics; Heisenberg limit; Rayleigh limit; entangled photons; image resolution; imaging system; quantum mechanical entanglement; quantum sensor miniaturization; satellite imaging; Apertures; Image resolution; Lithography; Optical imaging; Optical interferometry; Optoelectronic and photonic sensors; Quantum computing; Quantum entanglement; Satellites; Signal resolution; $N00N$ states; Entanglement; Rayleigh limit; quantum interferometry;

fLanguage

English

Journal_Title

Photonics Technology Letters, IEEE

Publisher

ieee

ISSN

1041-1135

Type

jour

DOI

10.1109/LPT.2007.906838

Filename

4367523