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    Journals >Infrared and Laser Engineering >Volume 52 >Issue 4 >Page 20220469 > Article
    • Infrared and Laser Engineering
    • Vol. 52, Issue 4, 20220469 (2023)
    Detection performance of spaceborne photon-counting LiDAR based on quantum enhancement
    Jun Hui, Hongzhou Chai, Minzhi Xiang, Zhenqiang Du, and Kaidi Jin
    Author Affiliations
  • College of Geospatial Information, Information Engineering University, Zhengzhou 450001, China
    • show less
    DOI: 10.3788/IRLA20220469 Cite this Article
    Jun Hui, Hongzhou Chai, Minzhi Xiang, Zhenqiang Du, Kaidi Jin. Detection performance of spaceborne photon-counting LiDAR based on quantum enhancement[J]. Infrared and Laser Engineering, 2023, 52(4): 20220469 Copy Citation Text show less
    References

    [1] K Kuzmenko, P Vines, A Halimi, et al. 3D LIDAR imaging using Ge-on-Si single–photon avalanche diode detectors. Optics Express, 28, 1330-1344(2020).

    [2] Yong Fang, Bincai Cao, Li Gao, et al. Development and application of lidar mapping satellite. Infrared and Laser Engineering, 49, 20201044(2020).

    [3] M Wilkinson, U Schreiber, I Procházka, et al. The next generation of satellite laser ranging systems. Journal of Geodesy, 93, 2227-2247(2019).

    [4] Xiangnan Liu, Yingfei Li, Chengyong Xiang, et al. Study on Integrated technique of laser ranging and communication and its applications in deep space. Journal of Deep Space Exploration, 5, 147-153(2018).

    [5] Hongbin Liu, Ming Li, Rong Shu, et al. Estimation and verification of high-accuracy laser ranging on several photons. Infrared and Laser Engineering, 48, 0106001(2019).

    [6] Ying Sun, Yan Liang. High-speed photon-number resolving detection with MPPC. Optical Instruments, 44, 22-28(2022).

    [7] L Cohen, E Matekole, Y Sher. Thresholded quantum LIDAR: Exploiting photon-number-resolving detection. Physical Review Letters, 123, 203601(2019).

    [8] C Wu, W Xing, L Xia, et al. Receiver performance characteristics of single-photon lidar in a strong background environment. Applied Optics, 58, 102-108(2019).

    [9] J Lin, H Huang. Receiver performance and detection statistics of single photon lidar. IET Radar, Sonar & Navigation, 14, 105-109(2020).

    [10] Zijing Zhang, Jiaheng Xie, Mingwei Huang, et al. Overview of quantum LiDAR (Invited). Infrared and Laser Engineering, 51, 20211102(2022).

    [11] Q Wang, L Hao, Y Zhang, et al. Optimal detection strategy for super-resolving quantum lidar. Journal of Applied Physics, 119, 023109(2016).

    [12] G Frascella, S Agne, F Khalili, et al. Overcoming detection loss and noise in squeezing-based optical sensing. NPJ Quantum Information, 7, 1-6(2021).

    [13] Li Gao, Xiaoli Zhang, Jingting Ma, et al. Quantum enhanced Doppler LiDAR based on integrated quantum squeezed light source(Invited). Infrared and Laser Engineering, 50, 20210031(2021).

    [14] Qiang Wang, Lili Hao, Hongxia Tang, et al. Effects of real environments on the performance of quantum Lidar. Infrared and Laser Engineering, 47, S106006(2018).

    [15] Q Wang, L Hao, Y Zhang, et al. Super-resolving quantum lidar: entangled coherent-state sources with binary-outcome photon counting measurement suffice to beat the shot-noise limit. Optics Express, 24, 5045-5056(2016).

    [16] Shu Wang, Yichong Ren, Ruizhong Rao, et al. Influence of atmosphere attenuation on quantum interferometric radar. Acta Physica Sinica, 66, 150301(2017).

    [17] G Spedalieri, S Pirandola. Optimal squeezing for quantum target detection. Physical Review Research, 3, L042039(2021).

    [18] R Nair. Quantum-limited loss sensing: Multiparameter estimation and bures distance between loss channels. Physical Review Letters, 121, 230801(2018).

    [19] T Gregory, P Moreau, S Mekhail, et al. Noise rejection through an improved quantum illumination protocol. Scientific Reports, 11, 21841(2021).

    [20] Doudou Lan, Xiaomin Guo, Chunsheng Peng, et al. Photon number distribution and second-order degree of coherence of a chaotic laser: analysis and experimental investigation. Acta Physica Sinica, 66, 120502(2017).

    [21] L Dovrat, M Bakstein, D Istrati, et al. Measurements of the dependence of the photon-number distribution on the number of modes in parametric down-conversion. Optics Express, 20, 2266-2276(2012).

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    Jun Hui, Hongzhou Chai, Minzhi Xiang, Zhenqiang Du, Kaidi Jin. Detection performance of spaceborne photon-counting LiDAR based on quantum enhancement[J]. Infrared and Laser Engineering, 2023, 52(4): 20220469
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