Super-resolution and super-sensitivity of entangled squeezed vacuum state using optimal detection strategy

doi:10.1088/1674-1056/26/9/094204

Abstract Interference metrology is a method for achieving high precision detection by phase estimation. The phase sensitivity of a traditional interferometer is subject to the standard quantum limit, while its resolution is constrained by the Rayleigh diffraction limit. The resolution and sensitivity of phase measurement can be enhanced by using quantum metrology. We propose a quantum interference metrology scheme using the entangled squeezed vacuum state, which is obtained using the magic beam splitter, expressed as |ψ > = (|ξ>|0 > + ≤ |0 > ≤|ξ>)/√2+2/coshr, such as the N00N state. We derive the phase sensitivity and the resolution of the system with Z detection, project detection, and parity detection. By simulation and analysis, we determine that parity detection is an optimal detection method, which can break through the Rayleigh diffraction limit and the standard quantum limit.

Keywords: entangled squeezed vacuum state quantum metrology parity detection

Received: 16 March 2017
Revised: 02 May 2017
Accepted manuscript online:

PACS:	42.50.-p	(Quantum optics)
	42.50.St	(Nonclassical interferometry, subwavelength lithography)
	42.50.Tx	(Optical angular momentum and its quantum aspects)

Corresponding Authors: Zijing Zhang, Yuan Zhao
E-mail: zhangzijing@hit.edu.cn;zhaoyuan@hit.edu.cn

Cite this article:

Jiandong Zhang(张建东), Zijing Zhang(张子静), Longzhu Cen(岑龙柱), Shuo Li(李硕), Yuan Zhao(赵远), Feng Wang(王峰) Super-resolution and super-sensitivity of entangled squeezed vacuum state using optimal detection strategy 2017 Chin. Phys. B 26 094204

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Super-resolution and super-sensitivity of entangled squeezed vacuum state using optimal detection strategy

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