Authors: Christian Bräuer-Burchardt, Peter Kühmstedt, Gunther Notni

Abstract:

A new hybrid method to realise high-precision distortion determination for optical ultra-precision 3D measurement systems based on stereo cameras using active light projection is introduced. It consists of two phases: the basic distortion determination and the refinement. The refinement phase of the procedure uses a plane surface and projected fringe patterns as calibration tools to determine simultaneously the distortion of both cameras within an iterative procedure. The new technique may be performed in the state of the device “ready for measurement" which avoids errors by a later adjustment. A considerable reduction of distortion errors is achieved and leads to considerable improvements of the accuracy of 3D measurements, especially in the precise measurement of smooth surfaces.

Keywords: 3D Surface Measurement, Fringe Projection, Lens Distortion, Stereo.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1075960

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References:

[1] Magill, A.A.: Variation in distortion with magnification. Journal of Research of the National Bureau of Standards 54(3) (1955) 153-142
[2] Brown, D.C.: Close-range camera calibration. Photogrammetric Engineering, 37(8) (1971) 855-866
[3] Fryer, J.G. and Brown, D.C.: Lens distortion for close range photogrammetry. Photogrammetric Engineering and Remote Sensing 52(1) (1986) 51-58.
[4] Fraser, C.S. and M.R. Shortis, M.R.: Variation of distortion within the photographic field. Photogrammetric Engineering and Remote Sensing, 58(6) (1992) 851-855
[5] Shortis, M.R., Robson, S., and Beyer, H.A.: Extended lens model calibration of digital still cameras. IAPRS 32(5) (1998) 159-164
[6] Dold, J.: Ein hybrides photogrammetrisches Industriemesssystem höchster Genauigkeit und seine ├£berpr├╝fung. PhD thesis, Universit├ñt der Bundeswehr
[7] Luhmann, T., Robson, S., Kyle, S., Harley, I.: Close range photogrammetry. Wiley Whittles Publishing (2006)
[8] Tsai, R.: An efficient and accurate camera calibration technique for 3-D machine vision. IEEE Proc CCVPR (1986) 364-74
[9] Weng, J., Cohen, P., Herniou, M.: Camera calibration with distortion models and accuracy evaluation, PAMI(14), No 11 (1992) 965-80
[10] Heikkilä, J. and Silven, O.: A four-step camera calibration procedure with implicit image correction. IEEE Proc CVPR (1997) 1106-1112
[11] Rahman, T. and Krouglicof, N.: An efficient camera calibration technique offering robustness and accuracy over a wide range of lens distortion. IEEE Trans. Image Processing, Vol 21(2) (2012) 626-637
[12] Devernay, F. and Faugeras, O.: Straight lines have to be straight. Mach. Vision Appl. 13 (2001)14-24
[13] Claus, D. and Fitzgibbon, A.W.: A rational function lens distortion model for general cameras.CVPR 1 (2005) 213-219
[14] Grompone von Gioi, R., Monasse, P., Morel, J.-M., and Tang, Z.: Towards high-precision lens distortion correction. Proc. ICIP (2010) 4237-4240
[15] Kruck, E.: BINGO Bundle Adjustment for Engineering Applications, Version 5.0. Software Reference Manual. Gesellschaft f├╝r Industriephotogrammetrie mbH Aalen (2003)
[16] Bräuer-Burchardt, C.: A simple new method for precise lens distortion correction of low cost camera systems. Pattern Recognition (Proc. 26th DAGM) LNCS (2004) 570-577
[17] Hanning, T.: High precision camera calibration with a depth dependent distortion mapping. Proc VIIP (2008) 304-309
[18] Schreiber, W. and Notni, G.: Theory and arrangements of selfcalibrating whole-body three-dimensional measurement systems using fringe projection techniques. Opt. Eng. 39 (2000) 159-169