[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.3807/JOSK.2016.20.1.107

Three Degrees of Freedom Global Calibration Method for Measurement Systems with Binocular Vision

Xu, Guan (Department of Vehicle Application Engineering, Traffic and Transportation College, Nanling Campus, Jilin University)
Zhang, Xinyuan (Department of Vehicle Application Engineering, Traffic and Transportation College, Nanling Campus, Jilin University)
Li, Xiaotao (Mechanical Science and Engineering College, Nanling Campus, Jilin University)
Su, Jian (Department of Vehicle Application Engineering, Traffic and Transportation College, Nanling Campus, Jilin University)
Lu, Xue (Department of Vehicle Application Engineering, Traffic and Transportation College, Nanling Campus, Jilin University)
Liu, Huanping (Department of Vehicle Application Engineering, Traffic and Transportation College, Nanling Campus, Jilin University)
Hao, Zhaobing (Department of Vehicle Application Engineering, Traffic and Transportation College, Nanling Campus, Jilin University)

Publication Information

Journal of the Optical Society of Korea / v.20, no.1, 2016 , pp. 107-117 More about this Journal

Abstract

We develop a new method to globally calibrate the feature points that are derived from the binocular systems at different positions. A three-DOF (degree of freedom) global calibration system is established to move and rotate the 3D calibration board to an arbitrary position. A three-DOF global calibration model is constructed for the binocular systems at different positions. The three-DOF calibration model unifies the 3D coordinates of the feature points from different binocular systems into a unique world coordinate system that is determined by the initial position of the calibration board. Experiments are conducted on the binocular systems at the coaxial and diagonal positions. The experimental root-mean-square errors between the true and reconstructed 3D coordinates of the feature points are 0.573 mm, 0.520 mm and 0.528 mm at the coaxial positions. The experimental root-mean-square errors between the true and reconstructed 3D coordinates of the feature points are 0.495 mm, 0.556 mm and 0.627 mm at the diagonal positions. This method provides a global and accurate calibration to unity the measurement points of different binocular vision systems into the same world coordinate system.

Keywords

Three-DOF; Global calibration; Binocular vision;

Citations & Related Records

Times Cited By KSCI : 6 (Citation Analysis)

Reference
Cited By KSCI

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