Ghost imaging for an axially moving target with an unknown constant speed

Xiaohui Li; Chenjin Deng; Mingliang Chen; Wenlin Gong; Shensheng Han

doi:10.1364/PRJ.3.000153

Journals >Photonics Research >Volume 3 >Issue 4 >Page 153 > Article

Photonics Research
Vol. 3, Issue 4, 153 (2015)

Ghost imaging for an axially moving target with an unknown constant speed

Xiaohui Li, Chenjin Deng, Mingliang Chen, Wenlin Gong^*, and Shensheng Han

Author Affiliations

Key Laboratory for Quantum Optics and Center for Cold Atom Physics, Shanghai Institute of Optics and Fine Mechanics,Chinese Academy of Sciences, Shanghai 201800, China

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DOI: 10.1364/PRJ.3.000153 Cite this Article Set citation alerts

Xiaohui Li, Chenjin Deng, Mingliang Chen, Wenlin Gong, Shensheng Han, "Ghost imaging for an axially moving target with an unknown constant speed," Photonics Res. 3, 153 (2015) Copy Citation Text

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Abstract

The influence of the axial relative motion between the target and the source on ghost imaging (GI) is investigated. Both the analytical and experimental results show that the transverse resolution of GI is reduced as the deviation of the target’s center position from the optical axis or the axial motion range increases. To overcome the motion blur, we propose a deblurring method based on speckle-resizing and speed retrieval, and we experimentally validate its effectiveness for an axially moving target with an unknown constant speed. The results demonstrated here will be very useful to forward-looking GI remote sensing.imaging;Image analysis

Keywords

Computational Image formation theory Quantum optics

Δ G^{(2, 2)} (x_{r}, x_{t}) = {| \int d x_{1} \int d x_{2} G^{(1, 1)} (x_{1}, x_{2}) h_{r}^{*} (x_{r}, x_{1}) h_{t} (x_{t}, x_{2}) |}^{2},

(1)

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h_{r} (x_{r}, x_{1}) \propto \exp {\frac{j π}{λ z} {(x_{r} - x_{1})}^{2}},

(2)

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h_{t} (x_{t}, x_{2}) \propto \int d x \exp {\frac{j π}{λ z_{1} (t)} {(x_{2} - x)}^{2}} t (x) h_{t} (x_{t}, x),

(3)

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G^{(1, 1)} (x_{1}, x_{2}) = I_{0} δ (x_{1} - x_{2}),

(4)

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Δ G^{(2, 2)} (x_{r}, x_{t}) \propto | \int d x \int d x_{2} t (x) \exp (\frac{j π}{λ z_{1} (t)} x^{2}) \times h_{t} (x_{t}, x) \exp [\frac{j π}{λ} (\frac{1}{z_{1} (t)} - \frac{1}{z}) x_{2}^{2}] {\times \exp [\frac{j 2 π}{λ} (\frac{x_{r}}{z} - \frac{x}{z_{1} (t)}) x_{2}] |}^{2} .

(5)

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Δ G^{(2, 2)} (x_{r}, x_{t}) \propto | \int d x t (x) \exp (\frac{j π}{λ z_{1} (t)} x^{2}) {\times h_{t} (x_{t}, x) sinc [\frac{D}{λ} (\frac{x_{r}}{z} - \frac{x}{z_{1} (t)})] |}^{2},

(6)

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Δ G^{(2, 2)} (x_{r}) = \int d x_{t} Δ G^{(2, 2)} (x_{r}, x_{t}) \propto \int d x {| t (x) |}^{2} {sinc}^{2} {\frac{D}{λ z} [x_{r} - M (t) x]},

(7)

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D (v) = \frac{\sum_{s = 1}^{K} {[B_{s} - B_{s}^{v}]}^{2}}{\sum_{s = 1}^{K} B_{s}^{2}},

(8)

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Xiaohui Li, Chenjin Deng, Mingliang Chen, Wenlin Gong, Shensheng Han, "Ghost imaging for an axially moving target with an unknown constant speed," Photonics Res. 3, 153 (2015)

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