Stereoscopic Light Stripe Scanning: Interference Rejection,Error Minimization and Calibration

Abstract

This paper addresses the problem of rejecting interference due to secondary specular reflections, cross-talk and other mechanisms in an active light stripe scanner for robotic applications. Conventional scanning methods control the environment to ensure the brightness of the stripe exceeds that of all other features. However, this assumption is likely to be violated for a robot operating in an uncontrolled environment. Robust scanning methods already exist, but suffer from problems including assumed scene structure, acquisition delay, lack of error recovery, and incorrect modeling of measurement noise. We propose a robust technique that overcomes these problems, using two cameras and knowledge of the light plane orientation to disambiguate the primary reflection from spurious measurements. Unlike other robust techniques, our validation and reconstruction algorithms are optimal with respect to sensor noise. Furthermore, we propose a procedure to calibrate the system using measurements of an arbitrary non-planar target, providing robust validation independently of ranging accuracy. Finally, our robust techniques allow the sensor to operate in ambient indoor light, allowing color and range to be implicitly registered. An experimental scanner demonstrates the effectiveness of the proposed techniques. Source code and sample data are provided in the multimedia extensions.

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References

Agin, G. J., and Binford, T. O. 1973. Computer description of curved objects . Proceedings of the 3rd International Joint Conference on Artificial Intelligence, Stanford, CA, August, pp. 629-640 .

Aldon, M. J., and Le Bris, L. 1994. Mobile robot localization using a light stripe sensor . Proceedings of the Intelligent Vehicles ’94 Symposium, Paris, France, October, pp. 255-259 .

Alshawish, H. M. M., and Allen, C. R. 1995. Third object recognition using coded light projection for robot assembly applications . Proceedings of the 21st International Conference on Industrial Electronics, Control and Instrumentation, Orlando, FL, Vol. 2, pp. 1420-1247 .

Bastuscheck, C. M. 1989. Techniques for real-time generation of range images . Proceedings of the IEEE Computer Society Conference on Computer Vision and Pattern Recognition, San Diego, CA, June, pp. 262-268 .

Besl, P. J. 1988. Active, optical range image sensors . Machine Vision Applications 1(2): 127-152 .

Clark, J., Trucco, E., and Cheung, H-F. 1995. Improving laser triangulation sensors using polarization . Proceedings of the 5th International Conference on Computer Vision, Cambridge, MA, June, pp. 981-986 .

Gruss, A., Carley, L. R., and Kanade, T. 1991. Integrated sensor and range-finding analog signal processor . IEEE Journal of Solid-State Circuits 26(3): 184-191 .

Hartley, R.I. 1999. Theory and practice of projective rectification . International Journal of Computer Vision 35(2): 115-127 .

Hartley, R. I., and Sturm, P. 1997. Triangulation . Computer Vision and Image Understanding 68(2): 146-157 .

10.

Hartley, R., and Zisserman, A. 2000. Multiple View Geometry in Computer Vision, Cambridge University Press, Cambridge .

11.

Haverinen, J., and Röning, J. 1998. An obstacle detection system using a light stripe identification based method . Proceedings of the IEEE International Joint Symposium on Intelligence and Systems, Rockville, MD, May, pp. 232-236 .

12.

Hebert, M. 2000. Active and passive range sensing for robotics . Proceedings of the IEEE International Conference on Robotics and Automation (ICRA), San Francisco, CA, April 24-28, pp. 102-110 .

13.

Hu, G., and Stockman, G. 1989. Three-dimensional surface solution using structured light and constraint propagation . IEEE Transactions on Pattern Analysis and Machine Intelligence 11(4): 390-402 .

14.

Huynh, D. Q., Owens, R. A., and Hartmann, P. E. 1999. Calibrating a structured light stripe system: a novel approach . International Journal of Computer Vision 33(1): 73-86 .

15.

Khadraoui, D., Motyl, G., Martinet, P., Gallice, J., and Chaumette, F. 1996. Visual servoing in robotics scheme using a camera/laser-stripe sensor . IEEE Transactions on Robotics and Automation 12(5): 743-750 .

16.

Magee, M., Weniger, R., and Franke, E. A. 1994. Location of features of known height in the presence of reflective and refractive noise using a stereoscopic light-striping approach . Optical Engineering 33(4): 1092-1098 .

17.

Moré, J. J., Garbow, B. S., and Hillstrom, K. E. 1980. Users’ guide for MINPACK-1. Technical Report ANL-80-74, Applied Mathematics Division, Argonne National Laboratory .

18.

Nakano, K., Watanabe, Y., and Kanno, S. 1988. Extraction and recognition of three-dimensional information by projecting a pair of slit-ray beams . Proceedings of the 9th International Conference on Pattern Recognition, Rome, Italy, November, pp. 736-738 .

19.

Nygards, J., and Wernersson, Å. 1994. Specular objects in range cameras: reducing ambiguities by motion . Proceedings of the of the IEEE International Conference on Multi-sensor Fusion and Integration for Intelligent Systems, Las Vegas, NV, October, pp. 320-328 .

20.

Nygards, J., Högström, T., and Wernersson, Å. 2000. Docking to pallets with feedback from a sheet-of-light range camera . Proceedings of the 2000 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Takamatsu, Japan, October 30-November 5, pp. 1853-1859 .

21.

Rao, K., Medioni, G., Liu, H., and Bekey, G. A. 1989. Shape description and grasping for robot hand-eye coordination . IEEE Control Systems Magazine 9: 22-29 .

22.

Shirai, Y., and Suwa, M. 1971. Recognition of polyhedrons with a range finder . Proceedings of the 2nd International Joint Conference on Artificial Intelligence, London, UK, September, pp. 80-87 .

23.

Tajima, J., and Iwakawa, M. 1990. Three-dimensional data acquisition by rainbow range finder . Proceedings of the 10th International Conference on Pattern Recognition, Atlantic City, NJ, June, Vol. 1, pp. 309-313 .

24.

Taylor, G., and Kleeman, L. 2001. Flexible self-calibrated visual servoing for a humanoid robot . Proceedings of the 2001 Australian Conference on Robotics and Automation, Sydney, Australia, November, pp. 79-84 .

25.

Taylor, G., and Kleeman, L. 2002. Grasping unknown objects with a humanoid robot . Proceedings of the 2002 Australiasian Conference on Robotics and Automation, Aukland, New Zealand, November, pp. 191-196 .

26.

Taylor, G., Kleeman, L., and Wernersson, Å. 2002. Robust color and range sensing for robotics applications using a stereoscopic light stripe scanner . Proceedings of the 2002 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), EPFL, Lausanne, Switzerland, September 30-October 4, pp. 178-183 .

27.

Trucco, E., and Fisher, R. B. 1994. Acquisition of consistent range data using local calibration . Proceedings of the 1994 IEEE International Conference on Robotics and Automation (ICRA), San Diego, CA, Vol. 4, pp. 3410-3415 .

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