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Laser & Optoelectronics Progress, Volume. 58, Issue 10, 1011016(2021)

Single-Photon Time-Resolved Imaging Spectroscopy Based on Compressed Sensing

Fan Liu1,3、†, Xuri Yao1,2、*†, Xuefeng Liu1,3、**, and Guangjie Zhai1,3
Author Affiliations
  • 1Key Laboratory of Electronics and Information Technology for Space Systems, National Space Science Center, Chinese Academy of Sciences, Beijing 100190, China
  • 2School of Physics, Beijing Institute of Technology, Beijing 100081, China
  • 3University of Chinese Academy of Sciences, Beijing 100049, China
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    AbstractGet PDF(in Chinese)
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    References (38)
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    Figures & Tables(16)
    Experimental setup for single-photon imaging with compressive sensing[30]

    Fig. 1. Experimental setup for single-photon imaging with compressive sensing[30]

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    Experimental results of single-photon imaging based on compressed sensing. (a) Compressive imaging results based on 0-1 matrices; (b) compressive imaging results based on complementary matrices; (c) imaging results based on point scanning; (d) single-photon imaging SNR as functions of number of effective photons[31]

    Fig. 2. Experimental results of single-photon imaging based on compressed sensing. (a) Compressive imaging results based on 0-1 matrices; (b) compressive imaging results based on complementary matrices; (c) imaging results based on point scanning; (d) single-photon imaging SNR as functions of number of effective photons[31]

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    Experimental setup for spectral compressive sensing measurement[32]

    Fig. 3. Experimental setup for spectral compressive sensing measurement[32]

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    Reconstruction results for 632.8-nm wavelength monochromatic light under different measurement methods[32]. (a) Non-negative matrix measurement; (b) mean subtraction process; (c) complementary matrix measurement; (d) original spectrum detected by a CCD under strong light

    Fig. 4. Reconstruction results for 632.8-nm wavelength monochromatic light under different measurement methods[32]. (a) Non-negative matrix measurement; (b) mean subtraction process; (c) complementary matrix measurement; (d) original spectrum detected by a CCD under strong light

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    Experimental setup of spectral imaging with a spectrometer[33]

    Fig. 5. Experimental setup of spectral imaging with a spectrometer[33]

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    Spectral imaging results of compressive sensing based on a spectrometer[33]. (a) Transmission spectrum of the object; (b1)-(b7) reconstructed images under different wavelengths; (b8) imaging result under full-rangewavelength

    Fig. 6. Spectral imaging results of compressive sensing based on a spectrometer[33]. (a) Transmission spectrum of the object; (b1)-(b7) reconstructed images under different wavelengths; (b8) imaging result under full-rangewavelength

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    Experimental setup of spectral imaging system with dual compressed sensing[35]

    Fig. 7. Experimental setup of spectral imaging system with dual compressed sensing[35]

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    Working time sequences of the dual-DMDs and PMT[35]

    Fig. 8. Working time sequences of the dual-DMDs and PMT[35]

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    Experimental results of spectral imaging based on cascade compressed sensing[35]. (a) Spectrum lines under different spatial modulations; (b) intensity fluctuations with different wavelengths of 530nm, 610nm, and all-spectrum; (c) imaging results with different wavelengths of 530nm, 610nm, and all-spectrum

    Fig. 9. Experimental results of spectral imaging based on cascade compressed sensing[35]. (a) Spectrum lines under different spatial modulations; (b) intensity fluctuations with different wavelengths of 530nm, 610nm, and all-spectrum; (c) imaging results with different wavelengths of 530nm, 610nm, and all-spectrum

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    Physical and structural drawings of rearranged fiber bundles

    Fig. 10. Physical and structural drawings of rearranged fiber bundles

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    Schematic of single-pixel 3D laser radar system[36]

    Fig. 11. Schematic of single-pixel 3D laser radar system[36]

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    Reconstruction results of single pixel lidar affected by stacking effect[36]. (a) Reconstruction results of “N”; (b) reconstruction results of “T”

    Fig. 12. Reconstruction results of single pixel lidar affected by stacking effect[36]. (a) Reconstruction results of “N”; (b) reconstruction results of “T”

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    Corrected image affected by stacking effect[36]

    Fig. 13. Corrected image affected by stacking effect[36]

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    Reconstruction result of the sparse matrix measurement[36]. (a) Number of “1” in each pattern is 1000; (b) number of “1” in each pattern is 500; (c) number of “1” in each pattern is 100; (d) number of “1” in each pattern is 50

    Fig. 14. Reconstruction result of the sparse matrix measurement[36]. (a) Number of “1” in each pattern is 1000; (b) number of “1” in each pattern is 500; (c) number of “1” in each pattern is 100; (d) number of “1” in each pattern is 50

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    Single-photon time-resolved imaging spectrometer

    Fig. 15. Single-photon time-resolved imaging spectrometer

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    • Table 1. Key performance indicators of single-photon time-resolved imaging spectrometer

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      Table 1. Key performance indicators of single-photon time-resolved imaging spectrometer

      ParameterValue
      Spectral response range/nm350—1800
      Imaging pixel1024×768
      Imaging resolution/(nm×nm)300×300
      Maximum spectral resolution/nm1
      Time measurement resolution/ps100
      Range of time measurement/μs0.06—5000
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    Fan Liu, Xuri Yao, Xuefeng Liu, Guangjie Zhai. Single-Photon Time-Resolved Imaging Spectroscopy Based on Compressed Sensing[J]. Laser & Optoelectronics Progress, 2021, 58(10): 1011016

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    Paper Information

    Category: Imaging Systems

    Received: Mar. 22, 2021

    Accepted: Apr. 23, 2021

    Published Online: May. 28, 2021

    The Author Email: Xuri Yao (yaoxuri@bit.edu.cn), Xuefeng Liu (liuxuefeng@nssc.ac.cn)

    DOI:10.3788/LOP202158.1011016

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology