"Multilevel symmetric pattern design and optimization for high-speed and high- accuracy 3D shape measurement," (2020)
/Y. Wang, J. S. Hyun, S. Zhang, B. Luo, Z. Liu, C. Jiang, B. Tao, "Multilevel symmetric pattern design and optimization for high-speed and high- accuracy 3D shape measurement," Optics and Laser Technology, 126, 106103 (2020); doi:10.1016/j.optlastec.2020.106103
Abstract
The binary defocusing technique has enabled speed breakthroughs for 3D shape measurement, yet simultaneously achieving high accuracy and high speed remains difficult. To overcome this limitation, we propose to utilize multilevel symmetric pattern for high-speed and high-accuracy 3D measurement. Compared to conventional binary patterns, multilevel pattern could bring more flexibility for eliminating undesired high-frequency harmonics, thus has the potential to greatly enhance the phase quality and measurement accuracy. In this paper, the symmetric pattern design principle and related optimization procedure were presented to find the best multilevel fringe patterns. Both simulation and experiments verify that comparing with conventional methods, the proposed method could consistently generate better fringe patterns for a wide range of fringe periods. Furthermore, we developed an absolute 3D shape measurement system with the speed of 667 Hz, verifying that the proposed method is applicable for high-speed, high-accuracy applications.