3D Measurement of Discontinuous Objects with Optimized Dual-frequency Grating Profilometry

Che, Jun; Sun, Yanxia; Jin, Xiaojun; Chen, Yong

doi:10.2478/msr-2021-0027

Abstract

Three-dimensional profilometry tends to be less effective at measuring discontinuous surfaces. To overcome this problem, an optimized profilometry based on fringe projection is proposed in this paper. Due to the limitation of the shooting angle, there are projection blind spots on the surface of discontinuous objects. Since the noises and unwrapping errors are always localized at the projection blind spots, an algorithm is designed to determine the blind spots automatically with the light intensity difference information. Besides, in order to improve the measurement accuracy, a processing scheme is introduced to deal with the local height distortion introduced by the dual-frequency grating profilometry. Lots of measurement tests on various surfaces are carried out to assess the optimized profilometry, and experimental results indicate that the modified profilometry system works more robust with high reliability and accuracy in measuring different kinds of surfaces, especially discontinuous ones.

References

[1] Luhmann, T., Robson, S., Kyle, S., Harley, I. (2006). Close Range Photogrammetry: Principles, Techniques and Applications. Whittles, ISBN 9781870325509.
Search in Google Scholar Back to article
[2] Hyun, J.S., Zhang, S. (2020). Influence of projector pixel shape on ultrahigh-resolution 3D shape measurement. Optics Express, 28 (7), 9510-9520.10.1364/OE.389331
Search in Google Scholar Back to article
[3] Zhang, S. (2018). High-speed 3D shape measurement with structured light methods: A review. Optics and Lasers in Engineering, 106, 119-131.10.1016/j.optlaseng.2018.02.017
Search in Google Scholar Back to article
[4] Qian, J., Feng, S., Li, Y., Tao, T., Han, J., Chen, Q., Zuo, C. (2020). Single-shot absolute 3D shape measurement with deep-learning-based color fringe projection profilometry. Optics Letters, 45 (7), 1842-1845.10.1364/OL.388994
Search in Google Scholar Back to article
[5] Zhou, P., Zhang, Y., Yu, Y., Cai, W., Zhou, G. (2020). 3D shape measurement based on structured light field imaging. Mathematical Biosciences and Engineering, 17 (1), 654-668.10.3934/mbe.2020034
Search in Google Scholar Back to article
[6] Zou, H., Da, F., Wang, Z. (2015). A novel 3D face feature based on Geometry image vertical shape information. Optik, 126 (9-10), 898-902.10.1016/j.ijleo.2015.02.083
Search in Google Scholar Back to article
[7] Huang, P.S., Zhang, S., Chiang, F.-P. (2005). Trapezoidal phase-shifting method for three-dimensional shape measurement. Optical Engineering, 44 (12), 123601.10.1117/1.2147311
Search in Google Scholar Back to article
[8] Quan, C., He, X., Tay, C.J., Shang, H.M. (2001). 3D surface profile measurement using LCD fringe projection. In Second International Conference on Experimental Mechanics. SPIE, vol. 4317.10.1117/12.429629
Search in Google Scholar Back to article
[9] Karpinsky, N., Zhang, S. (2012). High-resolution, real-time 3D imaging with fringe analysis. Journal of Real-Time Image Processing, 71, 55-66.10.1007/s11554-010-0167-4
Search in Google Scholar Back to article
[10] Takeda, M., Mutoh, K. (1983). Fourier transform profilometry for the automatic measurement of 3D object shape. Applied Optics, 22 (24), 3977-3982.10.1364/AO.22.003977
Search in Google Scholar Back to article
[11] Su, X., Chen, W. (2001). Fourier transform profilometry: A review. Optics and Lasers in Engineering, 35 (5), 263-284.10.1016/S0143-8166(01)00023-9
Search in Google Scholar Back to article
[12] Su, X., Chen, W., Zhang, Q., Chao, Y. (2001). Dynamic 3-D shape measurement method based on FTP. Optics and Lasers in Engineering, 36 (1), 49-64.10.1016/S0143-8166(01)00028-8
Search in Google Scholar Back to article
[13] Su, X., Su, L., Li, W., Xiang, L. (1998). New 3D profilometry based on modulation measurement. In Automated Optical Inspection for Industry: Theory, Technology, and Applications II. SPIE, vol. 3558.
Search in Google Scholar Back to article
[14] Goldstein, R.M., Zebker, H.A., Werner, C.L. (1988). Statellite radar interferometry: Two-dimensional phase unwrapping. Radio Science, 23 (4), 713-720.10.1029/RS023i004p00713
Search in Google Scholar Back to article
[15] Huntley, J.M., Saldner, H. (1993). Temporal phase-unwrapping algorithm for automated interferogram analysis. Applied Optics, 32 (17), 3047-3052.10.1364/AO.32.00304720829910
Search in Google Scholar Back to article
[16] Huntley, J.M., Coggrave, C.R. (1998). Progress in phase unwrapping. In International Conference on Applied Optical Metrology. SPIE, vol. 3407.10.1117/12.323298
Search in Google Scholar Back to article
[17] Chan, P.H., Bryanston-Cross, P.J., Parker, S.C. (1995). Fringe-pattern analysis using a spatial phase-stepping method with automatic phase unwrapping. Measurement Science and Technology, 6, 1250-1259.10.1088/0957-0233/6/9/004
Search in Google Scholar Back to article
[18] Yao, P., Gai, S., Chen, Y., Chen, W., Da, F. (2021). A multi-code 3D measurement technique based on deep learning. Optics and Lasers in Engineering, 143, 106623.10.1016/j.optlaseng.2021.106623
Search in Google Scholar Back to article
[19] Liu, Y., Fu, Y., Zhou, P., Zhuan, Y., Zhong, K., Guan, B. (2020). A real-time 3D shape measurement with color texture using a monochromatic camera. Optics Communications, 474, 126088.10.1016/j.optcom.2020.126088
Search in Google Scholar Back to article
[20] Wu, Z., Guo, W., Li, Y., Liu, Y., Zhang, Q. (2020). High-speed and high-efficiency three-dimensional shape measurement based on Gray-coded light. Photonics Research, 8 (6), 819-829.10.1364/PRJ.389076
Search in Google Scholar Back to article
[21] Guo, W., Wu, Z., Li, Y., Liu, Y., Zhang, Q. (2020). Real-time 3D shape measurement with dual-frequency composite grating and motion-induced error reduction. Optics Express, 28 (18), 26882-26897.10.1364/OE.40347432906954
Search in Google Scholar Back to article
[22] Zhang, J., Guo, W., Wu, Z., Zhang, Q. (2021). Three-dimensional shape measurement based on speckle-embedded fringe patterns and wrapped phase-to-height lookup table. Optical Review, 28, 227-238.10.1007/s10043-021-00653-9
Search in Google Scholar Back to article
[23] Zhang, S., Yau, S.T. (2007). Generic nonsinusoidal phase error correction for three-dimensional shape measurement using a digital video projector. Applied Optics, 46 (1), 36-43.10.1364/AO.46.00003617167551
Search in Google Scholar Back to article
[24] Hu, Y.S., Xi, J.T., Li, E.B., Chicharo, J., Yang, Z.K. (2006). Three-dimensional profilometry based on shift estimation of projected fringe patterns. Applied Optics, 45 (4), 678-687.10.1364/AO.45.00067816485679
Search in Google Scholar Back to article
[25] Gai, S., Da, F. (2011). A novel fringe adaptation method for digital projector. Optics and Lasers in Engineering, 49 (4), 547-552.10.1016/j.optlaseng.2010.12.004
Search in Google Scholar Back to article
[26] Jin, X., Chen, Y., Guo, Y., Sun, Y., Chen, J. (2013). Tea flushes identification based on machine vision for high-quality tea at harvest. Applied Mechanics and Materials, 288, 214-218.10.4028/www.scientific.net/AMM.288.214
Search in Google Scholar Back to article
[27] Jin, X., Chen, Y., Zhang, H., Sun, Y., Chen, J. (2012). High-quality tea flushes detection under natural conditions using computer vision. International Journal of Digital Content Technology and its Applications (Gyeongju), 6 (8), 600-606.
Search in Google Scholar Back to article
[28] Zhang, H., Chen, Y., Wang, W., Zhang, G. (2014). Positioning method or tea picking using active computer vision. Nongye Jixie Xuebao / Transactions of the Chinese Society of Agricultural Machinery, 45 (9), 61-65.
Search in Google Scholar Back to article
[29] Jin, X., Che, J., Chen, Y. (2021). Weed identification using deep learning and image processing in vegetable plantation. IEEE Access, 9, 10940-10950.10.1109/ACCESS.2021.3050296
Search in Google Scholar Back to article
[30] Jiang, H., Jiang, X., Ru, Y., Wang, J., Xu, L., Zhou, H. (2020). Application of hyperspectral imaging for detecting and visualizing leaf lard adulteration in minced pork. Infrared Physics & Technology, 110, 103467.10.1016/j.infrared.2020.103467
Search in Google Scholar Back to article

3D Measurement of Discontinuous Objects with Optimized Dual-frequency Grating Profilometry

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