Abstract
This chapter proposes a novel approach for the calibration of a panoramic camera using geometric information available in real scenes. Panoramic cameras are of increasing importance for various applications in computer vision, computer graphics or robotics. Previously developed camera calibration methods (for ‘standard’ camera architectures following the pinhole camera model) are not applicable due to the non-linearity of the panoramic camera, defined by the existence of multiple (nonlinear) optical centers and a cylindrical image manifold. This article addresses the calibration subject of a more general yet flexible panoramic camera model for the first time. The chapter focuses on the calibration of two dominant parameters that characterize the camera model and provide flexibility in selecting different types of panoramas such as single-center (e.g. as assumed for QTVR), symmetric stereo, concentric or polycentric panoramas. We elaborate selected geometric constraints (for increasing numerical stability) with the corresponding solutions; summarize the experimental results with captured image data, and discuss the performance of different geometric constraints via error-sensitivity simulation and analysis.
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References
S. E. Chen. QuickTimeVR-an image-based approach to virtual environment navigation. In Proc. SIGGRAPH’95, pages 29–38, Los Angeles, California, USA, August 1995. 335
O. Faugeras. Three-Dimensional Computer Vision: A Geometric Viewpoint. TheMIT Press, London, England, 1993. 337
P.E. Gill, W. Murray, and M.H. Wright. Practical Optimization. Academic Press, London, 1981. 343
F. Huang, S.-K. Wei, and R. Klette. Geometrical fundamentals of polycentric panoramas. In Proc. ICCV’01, pages I:560–565, Vancouver, Canada, July 2001. 335
H. Ishiguro, M. Yamamoto, and S. Tsuji. Omni-directional stereo. PAMI, 14(2):257–262, 1992. 335
R. Klette, K. SchlĂ¼ns, and A. Koschan. Computer Vision-Three-Dimensional Data from Images. Springer, Singapore, 1998. 336
L. McMillan and G. Bishop. Plenoptic modeling: an image-based rendering system. In Proc. SIGGRAPH’95, pages 39–46, Los Angeles, California, USA, August 1995. 335
H.-Y. Shum and L.-W. He. Rendering with concentric mosaics. In Proc. SIGGRAPH’99, pages 299–306, Los Angeles, California, USA, August 1999. 335
H.-Y. Shum and R. Szeliski. Stereo reconstruction from multiperspective panoramas. In Proc. ICCV’99, pages 14–21, Korfu, Greece, September 1999. 335
R.Y. Tsai. A versatile camera calibration technique for high-accuracy 3d machine vision metrology using off-the-shelf tv cameras and lenses. IEEE Journal of Robotics and Automation, 3(4):323–344, 1987. 337
S.-K. Wei, F. Huang, and R. Klette. Visibility determination in depth-layered cylinder scene representations. In Proc. IVCNZ’99, pages 175–180, Christchurch, New Zealand, August 1999. 335
J.-Y. Zheng and S. Tsuji. Panoramic representation for route recognition by a mobile robot. IJCV, 9(1):55–76, 1992. 335
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© 2003 Springer-Verlag Berlin Heidelberg
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Huang, F., Wei, S.K., Klette, R. (2003). Calibration of Panoramic Cameras Using 3D Scene Information. In: Asano, T., Klette, R., Ronse, C. (eds) Geometry, Morphology, and Computational Imaging. Lecture Notes in Computer Science, vol 2616. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-36586-9_21
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DOI: https://doi.org/10.1007/3-540-36586-9_21
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