• Infrared and Laser Engineering
  • Vol. 49, Issue 3, 0303010 (2020)
Yanjun Fu1, Yonghua Han1, Yuan Chen1, Pengfei Zhang1..., Jiannan Gui1, Kequn Zhong1 and Caimin Huang2|Show fewer author(s)
Author Affiliations
  • 1Key Laboratory of Nondestructive Testing, Education Ministry of China, Nanchang Hangkong University, Nanchang 330063, China
  • 2Dongguan Jiyang Automation Technology co. LTD, Dongguan 523000, China
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    DOI: 10.3788/IRLA202049.0303010 Cite this Article
    Yanjun Fu, Yonghua Han, Yuan Chen, Pengfei Zhang, Jiannan Gui, Kequn Zhong, Caimin Huang. Research progress of 3D measurement technology based on phase coding[J]. Infrared and Laser Engineering, 2020, 49(3): 0303010 Copy Citation Text show less
    References

    [1] M Takeda, K Mutoh. Fourier transform profilometry for the automatic measurement of 3-D object shapes. Applied Optics, 22, 3977-3982(1983).

    [2] F Chen, G M Brown, M Song. Overview of 3-D shape measurement using optical methods. Optical Engineering, 39, 1-22(2000).

    [3] D Bračun, A Sluga. Stereo vision based measuring system for online welding path inspection. Journal of Materials Processing Technology, 223, 328-336(2015).

    [4] Yanming Quan, Shumei Li, Qingqun Mai. The dimension of workpiece based on binocular vision is measured in three dimensions. Optics and Precision Engineering, 21, 1054-1061(2013).

    [5] A S Agatston, W R Janowitz, F J Hildner. Quantification of coronary artery calcium using ultrafast computed tomography. Journal of the American College of Cardiology, 15, 827-832(1990).

    [6] D J Brenner, E J Hall. Computed tomography—an increasing source of radiation exposure. New England Journal of Medicine, 357, 2277-2284(2007).

    [7] D Yuan, Feng Ye, Ling Yang. Research on interactive 3d measurement of medical images based on VTK. Computer Engineering and Design, 29, 3549-3550(2008).

    [8] W S Marras, S A Lavender, S E Leurgans. The role of dynamic three-dimensional trunk motion in occupationally-related. Spine, 18, 617-628(1993).

    [9] T B Moeslund, E Granum. A survey of computer vision-based human motion capture. Computer Vision and Image Understanding, 81, 231-268(2001).

    [10] J Steuer. Defining virtual reality: Dimensions determining telepresence. Journal of Communication, 42, 73-93(1992).

    [11] S S Gorthi, P Rastogi. Fringe projection techniques: whither we are?. Optics and Lasers in Engineering, 48, 133-140(2010).

    [12] S Zhang. Recent progresses on real-time 3D shape measurement using digital fringe projection techniques. Optics and Lasers in Engineering, 48, 149-158(2010).

    [13] C Zuo, L Huang, M Zhang. Temporal phase unwrapping algorithms for fringe projection profilometry: A comparative review. Optics and Lasers in Engineering, 85, 84-103(2016).

    [14] B Pan, Q Kemao, L Huang. Phase error analysis and compensation for nonsinusoidal waveforms in phase-shifting digital fringe projection profilometry. Optics Letters, 34, 416-418(2009).

    [15] Li S, Liu S, Zhang H. 3D shape measurement of optical freefm surface based on fringe projection[C]Optical Measurement Systems f Industrial Inspection VⅡ. International Society f Optics Photonics, 2011, 8082: 80822Z.

    [16] I Yamaguchi, T Zhang. Phase-shifting digital holography. Optics Letters, 22, 1268-1270(1997).

    [17] K Creath. Phase-shifting speckle interferometry. Applied Optics, 24, 3053-3058(1985).

    [18] A A Gastón, Matías Di Martino J, R A Julia. Three-dimensional profiling with binary fringes using phase-shifting interferome try algorithms. Applied Optics, 50, 147-154(2011).

    [19] C Zuo, S Feng, L Huang. Phase shifting algorithms for fringe projection profilometry: A review. Optics and Lasers in Engineering, 109, 23-59(2018).

    [20] T Zhang, I Yamaguchi. Three-dimensional microscopy with phase-shifting digital holography. Optics Letters, 23, 1221-1223(1998).

    [21] Takeda Mitsuo, Ina Hideki, Kobayashi Seiji. Fourier-transform method of fringe-pattern analysis for computer-based topography and interferometry. Journal of the Optical Society of America, 72, 156-160(1982).

    [22] Jian Li, Xianyu Su, Lurong Guo. An improved Fourier transform profilometry for automatic measurement of 3-D object shapes. Optics Engineering, 29, 1439-44(1990).

    [23] Xianyu Su, Wenjing Chen. Fourier transform profilomitry: a review. Optics and Lasers in Engineering, 35, 263-284(2001).

    [24] K Chen, J Xi, Y Yu. Quality-guided spatial phase unwrapping algorithm for fast three-dimensional measurement. Optics Communications, 294, 139-147(2013).

    [25] S Zhang. Absolute phase retrieval methods for digital fringe projection profilometry: A review. Optics and Lasers in Engineering, 107, 28-37(2018).

    [26] L Wu, Q Peng. Research and development of fringe projection-based methods in 3D shape reconstruction. Journal of Zhejiang University-Science A, 7, 1026-1036(2006).

    [27] Chen K, Xi J, Yu Y, et al. A composite qualityguided phase unwrapping algithm f fast 3D profile measurement[C]Optical Metrology Inspection f Industrial Applications Ⅱ. International Society f Optics Photonics, 2012, 8563: 856305.

    [28] J Geng. Structured-light 3D surface imaging: a tutorial. Advances in Optics and Photonics, 3, 128-160(2011).

    [29] H O Saldner, J M Huntley. Temporal phase unwrapping: application to surface profiling of discontinuous objects. Applied Optics,, 36, 2770-2775(1997).

    [30] G Du, C Zhang, C Zhou. Iterative two-step temporal phase-unwrapping applied to high sensitivity three-dimensional profilometry. Optics and Lasers in Engineering, 79, 22-28(2016).

    [31] J M Huntley, H O Saldner. Shape measurement by temporal phase unwrapping: comparison of unwrapping algorithms. Measurement Science and Technology, 8, 986(1997).

    [32] J Zhu, P Zhou, X Su. Accurate and fast 3D surface measurement with temporal-spatial binary encoding structured illumination. Optics Express, 24, 28549-28560(2016).

    [33] L L Li, X Y Su, Y F Dou. Error analysis and algorithm design of temporal phase unwrapping. Journal of Sichuan University (Natural Science Edition), 49, 102-108(2012).

    [34] J Tian, X Peng, X Zhao. A generalized temporal phase unwrapping algorithm for three-dimensional profilometry. Optics and Lasers in Engineering, 46, 336-342(2008).

    [35] M Servin, M Padilla, G Garnica. Profilometry of three-dimensional discontinuous solids by combining two-steps temporal phase unwrapping, co-phased profilometry and phase-shifting interferometry. Optics and Lasers in Engineering, 87, 75-82(2016).

    [36] Z H Xu, X Y Su. An algorithm of temporal phase unwrapping. J Sichuan University (Natural Science Edition), 45, 537-540(2008).

    [37] M Servin, F J Cuevas. A novel technique for spatial phase-shifting interferometry. Journal of Modern Optics, 42, 1853-1862(1995).

    [38] T Bothe, J Burke, H Helmers. Spatial phase shifting in electronic speckle pattern interferometry: minimization of phase reconstruction errors. Applied Optics, 36, 5310-5316(1997).

    [39] B Bhaduri, N K Mohan, M P Kothiyal. Use of spatial phase shifting technique in digital speckle pattern interferometry (DSPI) and digital shearography (DS). Optics Express, 14, 11598-11607(2006).

    [40] M F Salfity, P D Ruiz, J M Huntley. Branch cut surface placement for unwrapping of undersampled three-dimensional phase data: application to magnetic resonance imaging arterial flow mapping. Applied Optics, 45, 2711-2722(2006).

    [41] B Gutmann, H Weber. Phase unwrapping with the branch-cut method: clustering of discontinuity sources and reverse simulated annealing. Applied Optics, 38, 5577-5593(1999).

    [42] M Zhao, L Huang, Q Zhang. Quality-guided phase unwrapping technique: comparison of quality maps and guiding strategies. Applied Optics, 50, 6214-6224(2011).

    [43] S Zhang, X Li, S T Yau. Multilevel quality-guided phase unwrapping algorithm for real-time three-dimensional shape reconstruction. Applied Optics, 46, 50-57(2007).

    [44] Q Kemao, W Gao, H Wang. Windowed Fourier-filtered and quality-guided phase-unwrapping algorithm. Applied Optics, 47, 5420-5428(2008).

    [45] H Zhong, J Tang, S Zhang. An improved quality-guided phase-unwrapping algorithm based on priority queue. IEEE Geoscience and Remote Sensing Letters, 8, 364-368(2010).

    [46] J M Huntley, H Saldner. Temporal phase-unwrapping algorithm for automated interferogram analysis. Applied Optics, 32, 3047-3052(1993).

    [47] G Sansoni, M Carocci, R Rodella. Three-dimensional vision based on a combination of gray-code and phase-shift light projection: analysis and compensation of the systematic errors. Applied Optics, 38, 6565-6573(1999).

    [48] G Sansoni, S Corini, S Lazzari. Three-dimensional imaging based on Gray-code light projection: characterization of the measuring algorithm and development of a measuring system for industrial applications. Applied Optics, 36, 4463-4472(1997).

    [49] D Zheng, F Da. Self-correction phase unwrapping method based on Gray-code light. Optics and Lasers in Engineering, 50, 1130-1139(2012).

    [50] D Zheng, F Da, Q Kemao. Phase-shifting profilometry combined with Gray-code patterns projection: unwrapping error removal by an adaptive median filter. Optics Express, 25, 4700-4713(2017).

    [51] S Yu, J Zhang, X Yu. 3D measurement using combined Gray code and dual-frequency phase-shifting approach. Optics Communications, 413, 283-290(2018).

    [52] X Chen, J Xi, Y Jin. Phase error compensation method using smoothing spline approximation for a three-dimensional shape measurement system based on gray-code and phase-shift light projection. Optical Engineering, 47, 113601(2008).

    [53] H Nguyen, D Nguyen, Z Wang. Real-time, high-accuracy 3D imaging and shape measurement. Applied Optics, 54, A9-A17(2015).

    [54] L Chen, W Y Deng, X P Lou. Phase unwrapping method base on multi-frequency interferometry. Optical Technique, 38, 73-78(2012).

    [55] J Koo, T Cho. A 3D measurement system based on a double frequency method using Fourier transform profilometry. Journal of the Korea Institute of Information and Communication Engineering, 19, 1485-1492(2015).

    [56] Li B, Yang J, Wu H, et al. A new threedimensional shape measurement method based on doublefrequency fringes[C]AOPC 2015: Optical Test, Measurement, Equipment. International Society f Optics Photonics, 2015, 9677: 96770H.

    [57] Zhao H, Zhang C. Phase unwrapping algithm based on doublefrequency fringe projection fringe background[C]The International Conference on Photonics Optical Engineering (icPOE 2014). International Society f Optics Photonics, 2015, 9449: 944905.

    [58] Y Wang, J I Laughner, I R Efimov. 3D absolute shape measurement of live rabbit hearts with a superfast two-frequency phase-shifting technique. Optics Express, 21, 5822-5832(2013).

    [59] W H Su, H Liu. Calibration-based two-frequency projected fringe profilometry: a robust, accurate, and single-shot measurement for objects with large depth discontinuities. Optics Express, 14, 9178-9187(2006).

    [60] Y Ding, J Xi, Y Yu. Frequency selection in absolute phase maps recovery with two frequency projection fringes. Optics Express, 20, 13238-13251(2012).

    [61] Li Z, Shi Y, Wang C. Realtime complex object 3D measurement[C]2009 International Conference on Computer Modeling Simulation. IEEE, 2009: 191193.

    [62] Y Huang, Z Li, Y Shi. 3D measurement technology based on multifrequency heterodyne principle. New Technology & New Process, 12, 37-40(2008).

    [63] Liu S, Feng W, Zhang Q, et al. Threedimensional shape measurement of small object based on trifrequency heterodyne method[C]2015 International Conference on Optical Instruments Technology: Optoelectronic Measurement Technology Systems. International Society f Optics Photonics, 2015, 9623: 96231C.

    [64] Z Lei, C Wang, C Zhou. Multi-frequency inverse-phase fringe projection profilometry for nonlinear phase error compensation. Optics and Lasers in Engineering, 66, 249-257(2015).

    [65] Z Wang. Three-dimensional surface imaging by multi-frequency phase shift profilometry with angle and pattern modeling for system calibration. Measurement Science and Technology, 27, 085404(2016).

    [66] J S Hyun, S Zhang. Enhanced two-frequency phase-shifting method. Applied Optics, 55, 4395-4401(2016).

    [67] Li Z, Wang C. A prototype system f high precision 3D measurement based on grating method[C]Optical Design Testing Ⅲ. International Society f Optics Photonics, 2007, 6834: 683442.

    [68] H Q Huang, X Z Fang, W Zhang. Defocusing rectified multi-frequency patterns for high-precision 3D measurement. Measurement Science and Technology, 25, 035009(2014).

    [69] Lou X, Lv N, Sun P, et al. Heterodyne multifrequency method f 3D profile measurement[C]Fourth International Seminar on Modern Cutting Measurement Engineering. International Society f Optics Photonics, 2011, 7997: 799724.

    [70] Z Xiao, O Chee, A Asundi. An accurate 3D inspection system using heterodyne multiple frequency phase-shifting algorithm. Physics Procedia, 19, 115-121(2011).

    [71] Yao Y, Guo J. The 3D optical measurement system based on Multifrequency Heterodyne Principle[C]2012 7th International Conference on Computing Convergence Technology (ICCCT). IEEE, 2012: 11301134.

    [72] Wang L, Song L, Zhong L J, et al. Multifrequency heterodyne phase shift technology in 3D measurement[C]Advanced Materials Research. Trans Tech Publications, 2013, 774: 1582−1585.

    [73] Y Xu, S Jia, X Luo. Multi-frequency projected fringe profilometry for measuring objects with large depth discontinuities. Optics Communications, 288, 27-30(2013).

    [74] C Jiang, S Jia, J Dong. Multi-frequency color-marked fringe projection profilometry for fast 3D shape measurement of complex objects. Optics Express, 23, 24152-24162(2015).

    [75] Zhang X, Zhang Z, Cheng W. Iterative project calibration using multifrequency phaseshifting method[C]2015 IEEE 7th International Conference on Cyberics Intelligent Systems (CIS) IEEE Conference on Robotics, Automation Mechatronics (RAM). IEEE, 2015: 16.

    [76] L M Song, C M Chen, L Zhang. High precision global phase unwrapping method used in the multi-frequency 3D measurement. Opt Electron Eng, 39, 18-25(2012).

    [77] S Zhang, S T Yau. High-resolution, real-time 3D absolute coordinate measurement based on a phase-shifting method. Optics Express, 14, 2644-2649(2006).

    [78] P S Huang, S Zhang. Fast three-step phase-shifting algorithm. Applied Optics, 45, 5086-5091(2006).

    [79] Z Li, Y Shi, C Wang. Complex object 3D measurement based on phase-shifting and a neural network. Optics Communications, 282, 2699-2706(2009).

    [80] Huang P, Zhang S. 3d shape measurement system method including fast threestep phase shifting, err compensation calibration: U.S. Patent Application 11552, 520[P]. 2007524.

    [81] S Zhang. Composite phase-shifting algorithm for absolute phase measurement. Optics and Lasers in Engineering, 50, 1538-1541(2012).

    [82] S Zhang. High-resolution 3D profilometry with binary phase-shifting methods. Applied Optics, 50, 1753-1757(2011).

    [83] F Yang, X He. Two-step phase-shifting fringe projection profilometry: intensity derivative approach. Applied Optics, 46, 7172-7178(2007).

    [84] Zhang S. Digital multiple wavelength phase shifting algithm[C]Optical Inspection Metrology f NonOptics Industries. International Society f Optics Photonics, 2009, 7432: 74320N.

    [85] Y Wang, L Liu, J Wu. Dynamic three-dimensional shape measurement with a complementary phase-coding method. Optics and Lasers in Engineering, 127, 105982(2020).

    [86] Y Wang, S Zhang. Novel phase-coding method for absolute phase retrieval. Optics Letters, 37, 2067-2069(2012).

    [87] D Zheng, F Da. Phase coding method for absolute phase retrieval with a large number of codewords. Optics Express, 20, 24139-24150(2012).

    [88] C Zhou, T Liu, S Si. An improved stair phase encoding method for absolute phase retrieval. Optics and Lasers in Engineering, 66, 269-278(2015).

    [89] B Li, Y Fu, J Zhang. A fast three-dimensional shape measurement method based on color phase coding. Optik, 127, 1011-1015(2016).

    [90] B Li, Y Fu, J Zhang. Period correction method of phase coding fringe. Optical Review, 22, 717-723(2015).

    [91] Z Zeng, B Li, Y Fu. Stair phase-coding fringe plus phase-shifting used in 3D measuring profilometry. Journal of the European Optical Society-Rapid Publications, 12, 9(2016).

    [92] X Chen, Y Wang, Y Wang. Quantized phase coding and connected region labeling for absolute phase retrieval. Optics Express, 24, 28613-28624(2016).

    [93] Y Xing, C Quan, C J Tay. A modified phase-coding method for absolute phase retrieval. Optics and Lasers in Engineering, 87, 97-102(2016).

    [94] Q Zhang, X Su, L Xiang. 3-D shape measurement based on complementary Gray-code light. Optics and Lasers in Engineering, 50, 574-579(2012).

    [95] Y Wang, X Chen, L Huang. Improved phase-coding methods with fewer patterns for 3D shape measurement. Optics Communications, 401, 6-10(2017).

    [96] J S Hyun, S Zhang. Superfast 3D absolute shape measurement using five binary patterns. Optics and Lasers in Engineering, 90, 217-224(2017).

    [97] T Cheng, Q Du, Y Jiang. Absolute phase retrieval via color phase-coding. Optik, 140, 1056-1062(2017).

    [98] L Wang, Y Chen, X Han. A 3D shape measurement method based on novel segmented quantization phase coding. Optics and Lasers in Engineering, 113, 62-70(2019).

    [99] H Zhou, J Gao, H Hu. Fast phase-measuring profilometry through composite color-coding method. Optics Communications, 440, 220-228(2019).

    [100] Y Chen, X Han, P Zhang. 3D measurement method based on S-shaped segmental phase encoding. Optics and Laser Technology, 121, 105781(2020).

    [101] D Caspi, N Kiryati, J Shamir. Range imaging with adaptive color structured light. IEEE Transactions on Pattern Analysis and Machine Intelligence, 20, 470-480(1998).

    [102] Y Fu, Y Wang, M Wan. Three-dimensional profile measurement of the blade based on surface structured light. Optik, 124, 3225-3229(2013).

    [103] Xu Han, Lin Wang, Yanjun Fu. Phase unwrapping method of dual frequency heterodyne combined with phase coding. Infrared and Laser Engineering, 48, 09110031(2019).

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    Yanjun Fu, Yonghua Han, Yuan Chen, Pengfei Zhang, Jiannan Gui, Kequn Zhong, Caimin Huang. Research progress of 3D measurement technology based on phase coding[J]. Infrared and Laser Engineering, 2020, 49(3): 0303010
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