Precise and robust binocular camera calibration based on multiple constraints

Xia Liu; Zhenyu Liu; Guifang Duan; Jin Cheng; Xuetao Jiang; Jianrong Tan

doi:10.1364/AO.57.005130

Applied Optics
Vol. 57,
Issue 18,
pp. 5130-5140
(2018)
•https://doi.org/10.1364/AO.57.005130

Precise and robust binocular camera calibration based on multiple constraints

Xia Liu, Zhenyu Liu, Guifang Duan, Jin Cheng, Xuetao Jiang, and Jianrong Tan

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Xia Liu, Zhenyu Liu, Guifang Duan, Jin Cheng, Xuetao Jiang, and Jianrong Tan, "Precise and robust binocular camera calibration based on multiple constraints," Appl. Opt. 57, 5130-5140 (2018)

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Table of Contents Category
- Instrumentation, Measurement, and Metrology
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About this Article
History
- Original Manuscript: March 12, 2018
- Revised Manuscript: May 18, 2018
- Manuscript Accepted: May 20, 2018
- Published: June 15, 2018

Abstract

Precise calibration of a binocular vision system is the foundation of binocular vision measurement. In this paper, we propose a highly precise and robust binocular camera calibration method, which is devoted to minimize the error between the geometric relation of 3D reconstructed feature points and the ground truth, such as adjacent distance error, collinear error, and right-angle error. In addition, the reprojection error and epipolar are introduced to satisfy the homography relation and epipolar geometry theory better. We optimize all intrinsic parameters, extrinsic parameters, and distortion parameters to minimize the objective function, which is the sum of a series of nonlinear least squares terms. Levenberg–Marquardt iterative algorithm is used to find the optimal solution of the camera parameters. To test the precision and robustness of the proposed method, both actual measurement experiments and Gauss noise-adding experiments are carried out. The experimental results show that compared with the other two calibration methods in the contrast experiment, the distance measurement error, collinear error, and right-angle error are reduced dramatically. It is noticeable that in Gauss noise-adding experiments, the calibration parameters estimated by the proposed method are more stable.

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Method	$f_{x, l}$ (pixel)	$f_{y, l}$ (pixel)	$u_{0, l}$ (pixel)	$v_{0, l}$ (pixel)	$f_{x, r}$ (pixel)	$f_{y, r}$ (pixel)	$u_{0, r}$ (pixel)	$v_{0, r}$ (pixel)
Zhang’s method	3609.10	3607.39	1216.11	931.68	3610.90	3612.34	1247.54	926.76
Wang’s method	3607.93	3607.66	1216.25	931.17	3609.70	3611.40	1247.46	926.73
Our method	3607.57	3608.59	1216.32	931.64	3608.94	3609.97	1247.08	926.68

Method	$k_{1, l} ({mm}^{- 2})$	$k_{2, l} ({mm}^{- 4})$	$p_{1, l} ({mm}^{- 2})$	$p_{2, l} ({mm}^{- 2})$	$k_{1, r} ({mm}^{- 2})$	$k_{2, r} ({mm}^{- 4})$	$p_{1, r} ({mm}^{- 2})$	$p_{2, r} ({mm}^{- 2})$
Zhang’s method	−0.01136	0.16646	−0.00530	−0.00399	−0.04070	0.68782	−0.00613	0.00045
Wang’s method	−0.01882	0.21292	−0.00513	−0.00334	−0.04715	0.76520	−0.00613	0.00024
Our method	−0.02671	0.24460	−0.00481	−0.00268	−0.05601	0.84101	−0.00592	0.00026

Method	Rotation Matrix	Translation Matrix
Zhang’s method	$R = [\begin{matrix} 0.99998 & 0.00322 & - 0.00597 \\ - 0.00317 & 0.99997 & 0.00772 \\ 0.00599 & - 0.00770 & 0.99995 \end{matrix}]$	$T = [\begin{matrix} - 223.31727 \\ - 0.65144 \\ 4.32076 \end{matrix}]$
Wang’s method	$R = [\begin{matrix} 0.99997 & 0.00313 & - 0.00651 \\ - 0.00308 & 0.99997 & 0.00723 \\ 0.00653 & - 0.00721 & 0.99995 \end{matrix}]$	$T = [\begin{matrix} - 222.82322 \\ - 0.26677 \\ 4.11692 \end{matrix}]$
Our method	$R = [\begin{matrix} 0.99996 & 0.00289 & - 0.00792 \\ - 0.00284 & 0.99997 & 0.00661 \\ 0.00794 & - 0.00659 & 0.99995 \end{matrix}]$	$T = [\begin{matrix} - 221.58743 \\ 0.21295 \\ 5.23870 \end{matrix}]$

Method	$f_{x, l}$ (pixel)	$f_{y, l}$ (pixel)	$u_{0, l}$ (pixel)	$v_{0, l}$ (pixel)	$f_{x, r}$ (pixel)	$f_{y, r}$ (pixel)	$u_{0, r}$ (pixel)	$v_{0, r}$ (pixel)
Zhang’s method	3609.10	3607.39	1216.11	931.68	3610.90	3612.34	1247.54	926.76
Wang’s method	3607.93	3607.66	1216.25	931.17	3609.70	3611.40	1247.46	926.73
Our method	3607.57	3608.59	1216.32	931.64	3608.94	3609.97	1247.08	926.68

Method	$k_{1, l} ({mm}^{- 2})$	$k_{2, l} ({mm}^{- 4})$	$p_{1, l} ({mm}^{- 2})$	$p_{2, l} ({mm}^{- 2})$	$k_{1, r} ({mm}^{- 2})$	$k_{2, r} ({mm}^{- 4})$	$p_{1, r} ({mm}^{- 2})$	$p_{2, r} ({mm}^{- 2})$
Zhang’s method	−0.01136	0.16646	−0.00530	−0.00399	−0.04070	0.68782	−0.00613	0.00045
Wang’s method	−0.01882	0.21292	−0.00513	−0.00334	−0.04715	0.76520	−0.00613	0.00024
Our method	−0.02671	0.24460	−0.00481	−0.00268	−0.05601	0.84101	−0.00592	0.00026

Abstract

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Equations (31)

Applied Optics