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Laser & Optoelectronics Progress, Volume. 58, Issue 8, 0800001(2021)

Real-Time Three-Dimensional Imaging Technique Based on Phase-Shift Fringe Analysis: A Review

Wenbo Guo, Qican Zhang*, and Zhoujie Wu
Author Affiliations
  • Department of Opto-Electronics, College of Electronics and Information Engineering, Sichuan University, Chengdu, Sichuan 610065, China
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    References (124)
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    Figures & Tables(11)
    Schematic of 3D imaging technique based on phase-shift fringe analysis

    Fig. 1. Schematic of 3D imaging technique based on phase-shift fringe analysis

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    Main optimization approaches of real-time 3D measurement

    Fig. 2. Main optimization approaches of real-time 3D measurement

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    Installation diagram of fast projection equipment. (a) Laser interference fringe measurement system[33]; (b) light source stepping method phase shift projection equipment[34]; (c) array projection equipment[35]; (d) rotating projection measurement system[36]; (e) rotating structured light sequence projection equipment[38]; (f) 5D hyperspectral imaging system[40]; (g) rotating projection measurement system[43]; (h) MEMS galvanometer scanning projection measurement system[45]

    Fig. 3. Installation diagram of fast projection equipment. (a) Laser interference fringe measurement system[33]; (b) light source stepping method phase shift projection equipment[34]; (c) array projection equipment[35]; (d) rotating projection measurement system[36]; (e) rotating structured light sequence projection equipment[38]; (f) 5D hyperspectral imaging system[40]; (g) rotating projection measurement system[43]; (h) MEMS galvanometer scanning projection measurement system[45]

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    Fringe binarization. (a) Binary fringes; (b) local magnification; (c) binary fringe defocusing effect

    Fig. 4. Fringe binarization. (a) Binary fringes; (b) local magnification; (c) binary fringe defocusing effect

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    Schematic of phase unwrapping guided by fringe embedding auxiliary information. (a) De Bruijn sequence embedding four-step phase shift fringes[67]; (b) periodic signal embedding four-step phase shift fringes[68]; (c) speckle signal embedding three-step phase shift fringes[69]; (d) phase encoding embedding four-step phase shift fringes[21]

    Fig. 5. Schematic of phase unwrapping guided by fringe embedding auxiliary information. (a) De Bruijn sequence embedding four-step phase shift fringes[67]; (b) periodic signal embedding four-step phase shift fringes[68]; (c) speckle signal embedding three-step phase shift fringes[69]; (d) phase encoding embedding four-step phase shift fringes[21]

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    Gray code aided phase shift technique[72-73]. (a) Projected phase shift fringes; (b) projected Gray code fringes; (c) decoding process of the Gray codes; (d) decoding process of the complementary Gray codes

    Fig. 6. Gray code aided phase shift technique[72-73]. (a) Projected phase shift fringes; (b) projected Gray code fringes; (c) decoding process of the Gray codes; (d) decoding process of the complementary Gray codes

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    Schematic of improving Gray code efficiency. (a) Cyclic complementary Gray code aided phase shift method[74]; (b) shifting Gray code aided phase shift method[75]; (c) regional division phase unwrapping method and Gray code multiplexing coding strategy[76]; (d) ternary Gray code aided phase shift method[77]

    Fig. 7. Schematic of improving Gray code efficiency. (a) Cyclic complementary Gray code aided phase shift method[74]; (b) shifting Gray code aided phase shift method[75]; (c) regional division phase unwrapping method and Gray code multiplexing coding strategy[76]; (d) ternary Gray code aided phase shift method[77]

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    Schematic of multi-frequency fringes information multiplexing. (a) Dual-frequency composite phase shift method[79,8]; (b) 3+2 phase shift method[80,8]; (c) 2+2 phase shift method[81,8]

    Fig. 8. Schematic of multi-frequency fringes information multiplexing. (a) Dual-frequency composite phase shift method[79,8]; (b) 3+2 phase shift method[80,8]; (c) 2+2 phase shift method[81,8]

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    Schematic of multi-view stereo phase unwrapping and depth constraint[85]

    Fig. 9. Schematic of multi-view stereo phase unwrapping and depth constraint[85]

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    Real-time 3D shape measurement and motion error elimination method[100]. (a) Processing flow; (b) 3D reconstruction sequence

    Fig. 10. Real-time 3D shape measurement and motion error elimination method[100]. (a) Processing flow; (b) 3D reconstruction sequence

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    Some results of real-time 3D reconstruction

    Fig. 11. Some results of real-time 3D reconstruction

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    Wenbo Guo, Qican Zhang, Zhoujie Wu. Real-Time Three-Dimensional Imaging Technique Based on Phase-Shift Fringe Analysis: A Review[J]. Laser & Optoelectronics Progress, 2021, 58(8): 0800001

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    Paper Information

    Category: Reviews

    Received: Mar. 24, 2021

    Accepted: Apr. 9, 2021

    Published Online: Apr. 22, 2021

    The Author Email: Qican Zhang (zqc@scu.edu.cn)

    DOI:10.3788/LOP202158.0800001

    Topics

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