摘要
We establish a quantum theory of computational ghost imaging and propose quantum projection imaging where object information can be reconstructed by quantum statistical correlation between a certain photon number of a bucket signal and digital micromirror device random patterns. The reconstructed image can be negative or positive, depending on the chosen photon number. In particular, the vacuum state (zero-number) projection produces a negative image with better visibility and contrast-to-noise ratio. The experimental results of quantum projection imaging agree well with theoretical simulations and show that, under the same measurement condition, vacuum projection imaging is superior to conventional and fast first-photon ghost imaging in low-light illumination.
作者
Dezhong Cao
Suheng Zhang
Yanan Zhao
Cheng Ren
Jun Zhang
Baolai Liang
Baoqing Sun
Kaige Wang
曹德忠;张素恒;赵亚楠;任承;张骏;梁宝来;孙宝清;汪凯戈(Department of Physics,Yantai University,Yantai 264005,China;College of Physics Science&Technology,Hebei University,Baoding 071002,China;School of Information Science and Engineering,Shandong University,Qingdao 266237,China;Department of Physics,Applied Optics Beijing Area Major Laboratory,Beijing Normal University,Beijing 100875,China)
基金
financially supported by the National Natural Science Foundation of China (Nos. 12274037 and 11674273)
the Natural Science Foundation of Hebei Province (No. A202220103)。
