Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development
Fringe projector profilometry (FPP) is an important three-dimensional (3D) measurement technique, especially when high precision and speed are required. Thus, theoretical interrogation is critical to provide deep understanding and possible improvement of FPP. By dividing an FPP measurement process i...
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sg-ntu-dr.10356-1656452023-04-07T15:38:50Z Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development Lv, Shenzhen Tang, Dawei Zhang, Xuejun Yang, Dongyu Deng, Weijie Qian, Kemao School of Computer Science and Engineering Engineering::Computer science and engineering 3D Reconstruction Epipolar Line Fringe projector profilometry (FPP) is an important three-dimensional (3D) measurement technique, especially when high precision and speed are required. Thus, theoretical interrogation is critical to provide deep understanding and possible improvement of FPP. By dividing an FPP measurement process into four steps (system calibration, phase measurement, pixel correspondence, and 3D reconstruction), we give theoretical analysis on the entire process except for the extensively studied calibration step. Our study indeed reveals a series of important system properties, to the best of our knowledge, for the first time: (i) in phase measurement, the optimal and worst fringe angles are proven perpendicular and parallel to epipolar line, respectively, and can be considered as system parameters and can be directly made available during traditional calibration, highlighting the significance of the epipolar line; (ii) in correspondence, when two sets of fringes with different fringe orientations are projected, the highest correspondence precision can be achieved with arbitrary orientations as long as these two orientations are perpendicular to each other; (iii) in reconstruction, a higher reconstruction precision is given by the 4-equation methods, while we notice that the 3-equation methods are almost dominatingly used in literature. Based on these theoretical results, we propose a novel FPP measurement method which (i) only projects one set of fringes with optimal fringe angle to explicitly work together with the epipolar line for precise pixel correspondence; (ii) for the first time, the optimal fringe angle is determined directly from the calibration parameters, instead of being measured; (iii) uses 4 equations for precise 3D reconstruction but we can remove one equation which is equivalent to an epipolar line, making it the first algorithm that can use 3-equation solution to achieve 4-equation precision. Our method is efficient (only one set of fringe patterns is required in projection and the speed is doubled in reconstruction), precise (in both pixel correspondence and 3D reconstruction), and convenient (the computable optimal fringe angle and a closed-form 3-equation solution). We also believe that our work is insightful in revealing fundamental FPP properties, provides a more reasonable measurement for practice, and thus is beneficial to further FPP studies. Ministry of Education (MOE) Published version Funding: Ministry of Education - Singapore (MOE-T2EP20220-0008); Youth Innovation Promotion Association of the Chinese Academy of Sciences (2019221); National Natural Science Foundation of China (11903036, 1803037, 61805243, 62127901); Bureau of International Cooperation, Chinese Academy of Sciences (181722KYSB20180015); Key Research Program of Frontier Science, Chinese Academy of Sciences (QYZDJ-SSW-JSC038). 2023-04-05T07:42:10Z 2023-04-05T07:42:10Z 2022 Journal Article Lv, S., Tang, D., Zhang, X., Yang, D., Deng, W. & Qian, K. (2022). Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development. Optics Express, 30(19), 33515-33537. https://dx.doi.org/10.1364/OE.467502 1094-4087 https://hdl.handle.net/10356/165645 10.1364/OE.467502 36242386 2-s2.0-85138668435 19 30 33515 33537 en MOE-T2EP20220-0008 Optics Express © 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement. application/pdf |
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Engineering::Computer science and engineering 3D Reconstruction Epipolar Line Lv, Shenzhen Tang, Dawei Zhang, Xuejun Yang, Dongyu Deng, Weijie Qian, Kemao Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development |
| description |
Fringe projector profilometry (FPP) is an important three-dimensional (3D) measurement technique, especially when high precision and speed are required. Thus, theoretical interrogation is critical to provide deep understanding and possible improvement of FPP. By dividing an FPP measurement process into four steps (system calibration, phase measurement, pixel correspondence, and 3D reconstruction), we give theoretical analysis on the entire process except for the extensively studied calibration step. Our study indeed reveals a series of important system properties, to the best of our knowledge, for the first time: (i) in phase measurement, the optimal and worst fringe angles are proven perpendicular and parallel to epipolar line, respectively, and can be considered as system parameters and can be directly made available during traditional calibration, highlighting the significance of the epipolar line; (ii) in correspondence, when two sets of fringes with different fringe orientations are projected, the highest correspondence precision can be achieved with arbitrary orientations as long as these two orientations are perpendicular to each other; (iii) in reconstruction, a higher reconstruction precision is given by the 4-equation methods, while we notice that the 3-equation methods are almost dominatingly used in literature. Based on these theoretical results, we propose a novel FPP measurement method which (i) only projects one set of fringes with optimal fringe angle to explicitly work together with the epipolar line for precise pixel correspondence; (ii) for the first time, the optimal fringe angle is determined directly from the calibration parameters, instead of being measured; (iii) uses 4 equations for precise 3D reconstruction but we can remove one equation which is equivalent to an epipolar line, making it the first algorithm that can use 3-equation solution to achieve 4-equation precision. Our method is efficient (only one set of fringe patterns is required in projection and the speed is doubled in reconstruction), precise (in both pixel correspondence and 3D reconstruction), and convenient (the computable optimal fringe angle and a closed-form 3-equation solution). We also believe that our work is insightful in revealing fundamental FPP properties, provides a more reasonable measurement for practice, and thus is beneficial to further FPP studies. |
| author2 |
School of Computer Science and Engineering |
| author_facet |
School of Computer Science and Engineering Lv, Shenzhen Tang, Dawei Zhang, Xuejun Yang, Dongyu Deng, Weijie Qian, Kemao |
| format |
Article |
| author |
Lv, Shenzhen Tang, Dawei Zhang, Xuejun Yang, Dongyu Deng, Weijie Qian, Kemao |
| author_sort |
Lv, Shenzhen |
| title |
Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development |
| title_short |
Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development |
| title_full |
Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development |
| title_fullStr |
Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development |
| title_full_unstemmed |
Fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development |
| title_sort |
fringe projection profilometry method with high efficiency, precision, and convenience: theoretical analysis and development |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/165645 |
| _version_ |
1764208167786381312 |