Techniques of structured light measurement network with 3D sensors

Xiaoli Liu; Dong He; Hailong Chen; Zewei Cai; Yongkai Yin; Xiang Peng

doi:10.3378/IRLA202049.0303007

[1] G Sansoni, M Trebeschi, F Docchio. State-of-the-art and applications of 3D imaging sensors in industry, cultural heritage, medicine, and criminal investigation. Sensors, 9, 568-601(2009).

[2] H Schwenke, U Neuschaefer-Rube, T Pfeifer. Optical methods for dimensional metrology in production engineering. CIRP Annals-Manufacturing Technology, 51, 685-699(2002).

[3] F Blais. Review of 20 years of range sensor development. Journal of Electronic Imaging, 13, 231-240(2004).

[4] H A M Daanen, F B TerHaar. 3D whole body scanners revisited. Displays, 34, 270-275(2013).

[5] J Tong, J Zhou, L Liu. Scanning 3D full human bodies using kinects. IEEE Transactions on Visualization and Computer Graphics, 18, 643-650(2012).

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

[7] Jinying He, Xiaoli Liu, Xiang Peng. Integer pixel correlation searching for three-dimensional digital speckle based on gray constraint. Chinese Journal of Lasers, 44, 150-157(2017).

[8] Q Tang, C Liu, Z Cai. An improved spatiotemporal correlation method for high- accuracy random speckle 3D reconstruction. Optics and Lasers in Engineering, 110, 54-62(2018).

[9] C Zuo, T Tao, S Feng. Micro Fourier Transform Profilometry (μFTP): 3D shape measurement at 10,000 frames per second. Optics and Lasers in Engineering, 102, 70-91(2018).

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

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

[12] J Zhong, J Weng. Spatial carrier-fringe pattern analysis by means of wavelet transform: Wavelet transform profilometry. Applied Optics, 43, 4993-4998(2004).

[13] J Ma, Z Wang, B Pan. Two-dimensional continuous wavelet transform for phase determination of complex interferograms. Applied Optics, 50, 2425-2430(2011).

[14] M A Sutton, M Zhao, S R Mcneill. Development and assessment of a single-image fringe projection method for dynamic applications. Experimental Mechanics, 41, 205-217(2001).

[15] V Srinivasan, H C Liu, M Halioua. Automated phase-measuring profilometry of 3-d diffuse objects. Applied Optics, 23, 3105-3108(1984).

[16] J Peng, X Liu, D Deng. Suppression of projector distortion in phase-measuring profilometry by projecting adaptive fringe patterns. Optics Express, 24, 21846-21860(2016).

[17] J Pan, P S Huang, F P Chiang. Color-coded binary fringe projection technique for 3-D shape measurement. Optical Engineering, 44, 023606(2005).

[18] Z Zhang, C E Towers, D P Towers. Time efficient color fringe projection system for simultaneous 3D shape and color using optimum 3-frequency selection. Optics Express, 14, 6444-6455(2006).

[19] C Zuo, Q Chen, G Gu. High-speed three-dimensional shape measurement for dynamic scenes using bi-frequency tripolar pulse-width-modulation fringe projection. Optics and Lasers in Engineering, 51, 953-960(2013).

[20] S Lei, S Zhang. Flexible 3-D shape measurement using projector defocusing. Optics Letters, 34, 3080-3082(2009).

[21] S Heist, A Mann, P Kühmstedt. Array projection of aperiodic sinusoidal fringes for high-speed three-dimensional shape measurement. Optical Engineering, 53, 112208(2014).

[22] Y Guan, Y Yin, A Li. Dynamic 3D imaging based on acousto-optic heterodyne fringe interferometry. Optics Letters, 39, 3678-3681(2014).

[23] H Du, Z Wang. Three-dimensional shape measurement with an arbitrarily arranged fringe projection profilometry system. Optics Letters, 32, 2438-2440(2007).

[24] Z Huang, J Xi, Y Yu. Improved geometrical model of fringe projection profilometry. Optics Express, 22, 32220-32232(2014).

[25] Z Zhang, H Ma, S Zhang. Simple calibration of a phase-based 3D imaging system based on uneven fringe projection. Optics Letters, 36, 627-629(2011).

[26] A Asundi, Z Wensen. Unified calibration technique and its applications in optical triangular profilometry. Applied Optics, 38, 3556-3561(1999).

[27] L Huang, P S K Chua, A Asundi. Least-squares calibration method for fringe projection profilometry considering camera lens distortion. Applied Optics, 49, 1539-1548(2010).

[28] I Léandry, C Brèque, V Valle. Calibration of a structured-light projection system: development to large dimension objects. Optics and Lasers in Engineering, 50, 373-379(2012).

[29] R Legarda-Sáenz, T Bothe, W P Jüptner. Accurate procedure for the calibration of a structured light system. Optical Engineering, 43, 464-471(2004).

[30] Y Yin, X Peng, A Li. Calibration of fringe projection profilometry with bundle adjustment strategy. Optics Letters, 37, 542-544(2012).

[31] S Zhang, P S Huang. Novel method for structured light system calibration. Optical Engineering, 45, 083601(2006).

[32] X Chen, J Xi, Y Jin. Accurate calibration for a camera-projector measurement system based on structured light projection. Optics and Lasers in Engineering, 47, 310-319(2009).

[33] R Chen, J Xu, H Chen. Accurate calibration method for camera and projector in fringe patterns measurement system. Applied Optics, 55, 4293-4300(2016).

[34] J Vargas, J A Quiroga, M J Terron-Lopez. Flexible calibration procedure for fringe projection profilometry. Optical Engineering, 46, 023601(2007).

[35] J Huang, Q Wu. A new reconstruction method based on fringe projection of three-dimensional measuring system. Optics and Lasers in Engineering, 52, 115-122(2014).

[36] Z Cai, X Liu, A Li. Phase-3D mapping method developed from back-projection stereovision model for fringe projection profilometry. Optics Express, 25, 1262-1277(2017).

[37] J Guo, X Peng, A Li. Automatic and rapid whole-body 3D shape measurement based on multinode 3D sensing and speckle projection. Applied Optics, 56, 8759-8768(2017).

[38] X Peng, X Liu, Y Yin. Optical measurement network for large-scale and shell-like objects. Optics Letters, 36, 157-159(2011).

[39] X Liu, X Peng, H Chen. Strategy for automatic and complete three-dimensional optical digitization. Optics Letters, 37, 3126-3128(2012).

[40] Xiaoli Liu, Xiang Peng, Yongkai Yin. 3D auto-inspection for large thin-wall object. Acta Optica Sinica, 31, 0312006(2011).

[41] S Y Chen, Y F Li. Automatic sensor placement for model-based robot vision. Part B: Cybernetics, IEEE Transactions on Systems, Man, and Cybernetics, 34, 393-408(2004).

[42] K A Tarabanis, P K Allen, R Y Tsai. A survey of sensor planning in computer vision. IEEE Transactions on Robotics and Automation, 11, 86-104(1995).

[43] W R Scott. Model-based view planning. Machine Vision and Applications, 20, 47-69(2009).

[44] X Liu, Z Cai, Y Yin. Calibration of fringe projection profilometry using an inaccurate 2D reference target. Optics and Lasers in Engineering, 89, 131-137(2017).

[45] D He, X Liu, X Peng. Eccentricity error identification and compensation for high-accuracy 3D optical measurement. Measurement Science and Technology, 24, 075402(2013).

[46] Yongkai Yin, Xiaoli Liu, Ameng Li. Sub-pixel location of circle target and its application. Infrared and Laser Engineering, 37, 47-50(2008).

[47] Y Yin, X Peng, X Liu. Calibration strategy of optical measurement network for large-scale and shell-like objects. Optics Communications, 285, 2048-2056(2012).

[48] P J Besl, N D McKay. A method for registration of 3D shapes. IEEE Transactions on Pattern Analysis and Machine Intelligence, 14, 239-256(1992).

[49] J Salvi, C Matabosch, D Fofi. A review of recent range image registration methods with accuracy evaluation. Image and Vision Computing, 25, 578-596(2007).

[50] Liu Xiaoli. Key techniques in multiple range images modeling [D]. Tianjin: Tianjin University, 2008. (in Chinese)

[51] Liu X, Peng X, He D, et al. Automatic 3D imaging modeling system with col infmation f cultural heritage digitization [C]Fringe 2013, 2013: 821826.

[52] A Li, X Peng, Y Yin. Optical 3D digitizer for photorealistic imaging of movable cultural heritage. Acta Photonica Sinica, 42, 1421-1429(2013).

[53] X Liu, X Peng, Y Yin. Generation of photorealistic 3D image using optical digitizer. Applied Optics, 51, 1304-1311(2012).

[54] Xiaoli Liu, Xiang Peng, Yongkai Yin. A method for global registration of range data combined with markers. Acta Optica Sinica, 29, 1010-1014(2009).

[55] Liu X, He X, Liu Z, et al. Automatic registration of range images combined with the system calibration global ICP [C]SPIE, 2012: 84991X.

[56] Xiaoli Liu, Xiang Peng, Yongkai Yin. Introduction and comparison of range image registration methods. Laser & Optoelectronics Progress, 47, 121001(2010).

[57] Xiaoli Liu, Xiang Peng, Ameng Li. Range images registration combined with texture information. Journal of Computer-aided Design & Computer Graphics, 19, 340-345(2007).

[58] Xingming Liu, Xiaoli Liu, Yongkai Yin. Texture blending of 3D photo-realistic model. Journal of Computer-aided Design & Computer Graphics, 24, 1440-1446(2012).

[59] X Liu, A Li, X Zhao. Model-based optical metrology and visualization of 3-D complex objects. Optoelectronics Letters, 3, 115-118(2007).

[60] Xiaoli Liu, Xiang Peng, Ameng Li. Integration of multiple range images based on ray casting. Journal of Computer-aided Design & Computer Graphics, 19, 1286-1291(2007).

CLP Journals