Measurement of absolute three-dimensional displacement gradients using tri-color quad-beam digital shearography

Xuan Li; Sijin Wu; Xiaojun Tang; Weixian Li

doi:10.1007/s11801-023-3007-z

Optoelectronics Letters ›› 2023, Vol. 19 ›› Issue (8) : 487 -492. DOI: 10.1007/s11801-023-3007-z

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Measurement of absolute three-dimensional displacement gradients using tri-color quad-beam digital shearography

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Abstract

A tri-color quad-beam digital shearography is proposed to achieve the measurement of absolute three-dimensional (3D) displacement gradients. Four laser beams with three different center wavelengths are symmetrically irradiated to the object surface from the upper and lower left and right directions. Four phase maps are then extracted from the two interferograms obtained from two shots. Based on these four phase maps, the absolute 3D displacement gradients are determined. This means of absolute 3D displacement gradient measurement effectively improves the measurement capability of digital shearography and expands its application range.

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Xuan Li, Sijin Wu, Xiaojun Tang, Weixian Li. Measurement of absolute three-dimensional displacement gradients using tri-color quad-beam digital shearography. Optoelectronics Letters, 2023, 19(8): 487-492 DOI:10.1007/s11801-023-3007-z

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References

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[1]	LeendertJ A, ButtersJ N. An image-shearing speckle-pattern interferometer for measuring bending moments[J]. Journal of physics E: scientific instruments, 1973, 6(11):1107-1110

[2]	WangY H, YaoY F, LiJ R, et al.. Progresses of shearography: key technologies and applications[J]. Laser & optoelectronics progress, 2022, 59(14):53-61

[3]	ZhaoQ H, ChenW J, SunF Y, et al.. Simultaneous 3D measurement of deformation and its first derivative with speckle pattern interferometry and shearography[J]. Applied optics, 2019, 58(31):8665-8672

[4]	WuS J, LiX, LiW X, et al.. Non-contact and fast measurement of small roll angle using digital shearography[J]. Optics and lasers in engineering, 2022, 150: 106846

[5]	YanP Z, SunF Y, DanX Z, et al.. Spatial phase-shift digital shearography for simultaneous measurements in three shearing directions based on adjustable aperture multiplexing[J]. Optical engineering, 2019, 58(5):054105

[6]	WangH Y, LiuC Y, WuS J, et al.. Simultaneous measurement of three-dimensional displacement gradients using tri-color digital shearography[J]. Instruments and experimental techniques, 2021, 64(1): 165-171

[7]	WuS J, ZhuL Q, PanS Y, et al.. Spatiotemporal three-dimensional phase unwrapping in digital speckle pattern interferometry[J]. Optics letters, 2016, 41(5):1050-1053

[8]	NavarroM A, EstradaJ C, ServinM, et al.. Fast two-dimensional simultaneous phase unwrapping and low-pass filtering[J]. Optics express, 2012, 20(3):2556-2561

[9]	LiZ S, ZhongP, ChenY, et al.. Simultaneous measurement of three-dimensional deformation based on digital speckle pattern interferometry technology[J]. Optics communications, 2021, 480: 126423

[10]	WuS L, SunF Y, XieH T, et al.. Inverse algorithm for out-of-plane deformation in shearography[J]. Optical and quantum electronics, 2021, 53(1):43

[11]	BaiP X, ZhuF P, HeX Y. Out-of-plane displacement field measurement by shearography[J]. Optics & laser technology, 2015, 73: 29-38

[12]	HuntleyJ M, SaldnerH O. Temporal phase unwrapping algorithm for automated interferogram analysis[J]. Applied optics, 1993, 32(17):3047-3052

[13]	StetsonK A. Use of sensitivity vector variations to determine absolute displacements in double exposure hologram interferometry[J]. Applied optics, 1990, 29(4):502-504

[14]	SiebertT, SplitthofK, EttemeyerA. A practical approach to the problem of the absolute phase in speckle interferometry[J]. Journal of holography & speckle, 2004, 1(1):32-38

[15]	GaoX Y, WangY H, LiJ R, et al.. Spatial carrier color digital speckle pattern interferometry for absolute three-dimensional deformation measurement[J]. Optical engineering, 2017, 56(6): 066107