Reconstruction method for fringe projection profilometry based on light beams

Xuexing Li; Zhijiang Zhang; Chen Yang

doi:10.1364/AO.55.009895

Applied Optics
Vol. 55,
Issue 34,
pp. 9895-9906
(2016)
•https://doi.org/10.1364/AO.55.009895

Reconstruction method for fringe projection profilometry based on light beams

Xuexing Li, Zhijiang Zhang, and Chen Yang

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Xuexing Li, Zhijiang Zhang, and Chen Yang, "Reconstruction method for fringe projection profilometry based on light beams," Appl. Opt. 55, 9895-9906 (2016)

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Abstract

A novel reconstruction method for fringe projection profilometry, based on light beams, is proposed and verified by experiments. Commonly used calibration techniques require the parameters of projector calibration or the reference planes placed in many known positions. Obviously, introducing the projector calibration can reduce the accuracy of the reconstruction result, and setting the reference planes to many known positions is a time-consuming process. Therefore, in this paper, a reconstruction method without projector’s parameters is proposed and only two reference planes are introduced. A series of light beams determined by the subpixel point-to-point map on the two reference planes combined with their reflected light beams determined by the camera model are used to calculate the 3D coordinates of reconstruction points. Furthermore, the bundle adjustment strategy and the complementary gray-code phase-shifting method are utilized to ensure the accuracy and stability. Qualitative and quantitative comparisons as well as experimental tests demonstrate the performance of our proposed approach, and the measurement accuracy can reach about 0.0454 mm.

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	LPIM [32]	EFM [33]	WSTM [34]	Our Proposed
1	50.2430	50.3234	49.9370	50.0574
2	50.2764	50.3756	49.9453	50.0632
3	50.3205	50.4277	49.9267	50.0496
Average values	50.2800	50.3756	49.9363	50.0567
Variation	0.2785	0.3741	0.0652	0.0552

	$A$		$K$	$G$	$M_{0}$		$μ$	Error ( $6 σ)$
	$f_{u}$ , $f_{v}$	$u_{0}$ , $v_{0}$	$k_{1}$ , $k_{2}$ , $k_{3}$	$g_{1}$ , $g_{2}$	$R_{0}$	$T_{0}$	$μ$	$u$ , $v$
Zhang [27]	2201.5257 2194.2639	374.4236 174.8906	−0.1114 0.2087 0	−0.0062 0.0128	0.9878, 0.0037, −0.1556 0.0012, −0.9999, −0.0161 −0.1556, 0.0158, −0.9877	−92.4299 101.6375 996.9995	/	0.766468 0.685766
BA	2201.6660 2194.2921	374.4276 174.8852	−0.1120 0.2868 −0.0236	−0.0060 0.0130	0.9878, 0.0037, −0.1558 0.0012, −0.9999, −0.0162 −0.1559, 0.0158, −0.9877	−92.2094 101.3841 994.5140	0.997507	0.633681 0.595972

Reference Plane Pair	$h$	Center Point of the Fitted Plane	Estimated Value (mm)	Absolute Error (mm)
$(η_{0}, η_{20})$	20	−58.9641, 63.8754, 957.2586	40.1161	0.1161
$(η_{0}, η_{60})$	60	−59.0197, 63.8747, 957.1958	40.0454	0.0454
$(η_{0}, η_{80})$	80	−59.0282, 63.8683, 957.1522	40.0496	0.0496
$(η_{0}, η_{100})$	100	−59.0232, 63.8672, 957.0988	40.0511	0.0511

	Test Group		Control Group
	$d$ (mm)	$α (°)$	$d$ (mm)	$α (°)$
1	87.6943	135.3066	87.9267	135.9456
2	87.6467	135.3043	87.8861	135.4315
3	87.5966	134.8678	88.1792	134.8667
Average values	87.6459	135.1596	87.9973	135.4146
Variation	0.2203	0.2639	0.2410	0.2970
Relative errors	0.2520%	0.1949%	0.2731%	0.2188%

	LPIM [32]	EFM [33]	WSTM [34]	Our Proposed
1	50.2430	50.3234	49.9370	50.0574
2	50.2764	50.3756	49.9453	50.0632
3	50.3205	50.4277	49.9267	50.0496
Average values	50.2800	50.3756	49.9363	50.0567
Variation	0.2785	0.3741	0.0652	0.0552

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Applied Optics