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    Journals >Laser & Optoelectronics Progress >Volume 58 >Issue 10 >Page 1011017 > Article
    • Laser & Optoelectronics Progress
    • Vol. 58, Issue 10, 1011017 (2021)
    Correlation Imaging Research Under Disturbance of Channel Airflow
    Xiquan Fu*†, Xianwei Huang, Wei Tan, and Yanfeng Bai
    Author Affiliations
  • College of Computer Science and Electronic Engineering, Hunan University, Changsha, Hunan 410082, China
    • show less
    DOI: 10.3788/LOP202158.1011017 Cite this Article Set citation alerts
    Xiquan Fu, Xianwei Huang, Wei Tan, Yanfeng Bai. Correlation Imaging Research Under Disturbance of Channel Airflow[J]. Laser & Optoelectronics Progress, 2021, 58(10): 1011017 Copy Citation Text show less
    Experimental principle of the laser transmission in a wind tunnel[42]
    Fig. 1. Experimental principle of the laser transmission in a wind tunnel[42]
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    Influence of the wind speed on the average beam deflection. (a) Airflow interval is 0.45 m; (b) airflow interval is 1.38 m; (c) airflow interval is 2.31 m[42]
    Fig. 2. Influence of the wind speed on the average beam deflection. (a) Airflow interval is 0.45 m; (b) airflow interval is 1.38 m; (c) airflow interval is 2.31 m[42]
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    Correlation imaging experimental device under different wind speeds[49]
    Fig. 3. Correlation imaging experimental device under different wind speeds[49]
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    Imaging results under different wind speeds. (a)--(d) Correlation imaging experiment results under different wind speeds; (e) experiment and simulation results under different wind speeds; (f) experiment and simulation results under different sampling times[49]
    Fig. 4. Imaging results under different wind speeds. (a)--(d) Correlation imaging experiment results under different wind speeds; (e) experiment and simulation results under different wind speeds; (f) experiment and simulation results under different sampling times[49]
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    Correlation imaging scheme under high-speed airflow[49]
    Fig. 5. Correlation imaging scheme under high-speed airflow[49]
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    Correlation imaging results under different wind speeds. (a) M=0.5Ma; (b) M=1.5Ma; (c) M=2Ma; (d) M=3Ma[49]
    Fig. 6. Correlation imaging results under different wind speeds. (a) M=0.5Ma; (b) M=1.5Ma; (c) M=2Ma; (d) M=3Ma[49]
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    Influence of different boundary layer thicknesses on imaging results when M=1.5Ma. (a) Boundary layer thickness is 20 mm; (b) boundary layer thickness is 80 mm; (c) boundary layer thickness is 150 mm[49]
    Fig. 7. Influence of different boundary layer thicknesses on imaging results when M=1.5Ma. (a) Boundary layer thickness is 20 mm; (b) boundary layer thickness is 80 mm; (c) boundary layer thickness is 150 mm[49]
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    Influence of wind speed and turbulence intensity on image quality[49]
    Fig. 8. Influence of wind speed and turbulence intensity on image quality[49]
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    Experimental setup of the correlation imaging for detecting trembling[52]
    Fig. 9. Experimental setup of the correlation imaging for detecting trembling[52]
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    Imaging results of the trembling in different directions. (a) x direction; (b) y direction[52]
    Fig. 10. Imaging results of the trembling in different directions. (a) x direction; (b) y direction[52]
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    Imaging results under different trembling conditions. (a) No trembling; (b) irregular trembling[52]
    Fig. 11. Imaging results under different trembling conditions. (a) No trembling; (b) irregular trembling[52]
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    Object information detection method and detection results. (a) Flow chart of the object area detection. (b)--(c) center of the object area under different imaging intervals; (d) SNR of the reconstructed target under different imaging intervals[52]
    Fig. 12. Object information detection method and detection results. (a) Flow chart of the object area detection. (b)--(c) center of the object area under different imaging intervals; (d) SNR of the reconstructed target under different imaging intervals[52]
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    Reconstructed image of the target. (a) No trembling; (b) with trembling; (c) imaging result of the improved algorithm; (d) imaging result of the cross-correlation algorithm[52]
    Fig. 13. Reconstructed image of the target. (a) No trembling; (b) with trembling; (c) imaging result of the improved algorithm; (d) imaging result of the cross-correlation algorithm[52]
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    Xiquan Fu, Xianwei Huang, Wei Tan, Yanfeng Bai. Correlation Imaging Research Under Disturbance of Channel Airflow[J]. Laser & Optoelectronics Progress, 2021, 58(10): 1011017
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    Paper Information
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