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Rectification of Stereo Images

Rectification of Stereo Images. Милош Миловановић Урош Поповић. Camera Model. c – optical center R – retinal plane F – focal plane f – focal length. Stereo Images. Epipolar Geometry. m 1 , m 2 – conjugated points m 1 c 1 c 2 – epipolar plane

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Rectification of Stereo Images

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  1. Rectification of Stereo Images Милош Миловановић Урош Поповић

  2. Camera Model c – optical center R – retinal plane F – focal plane f – focal length

  3. Stereo Images

  4. Epipolar Geometry m1, m2– conjugated points m1c1c2– epipolar plane m2e2 – eipiolar line conjugated to m1 e1=c1c2R1 – first epipole e2=c1c2R2– second epipole Rectification: e1 , e2

  5. Fundamental Matrix m1=(x1,y1,1) m2=(x2 y2,1) m2line(Am1,e2) m2∙(Am1 X e2)=0 m2tFm1=0 m1t Ft m2=0 Rank F=2 m2t Fe1=0 for all m2 Fe1=0, Fte2=0 Am1

  6. Estimating of Fundamental Matrix 8 points to estimate F up to a constant factor Singular value decomposition

  7. Rectification x=0 – invariant points

  8. Better solution H=GRT T – translation central point to the origin R – rotation epipole to be on X-axis G – projective transform

  9. R. I. Hartley, Theory and practice of projective rectification, International Journal of Computer Vision 35 (2) (1999) 115–127. • C. Loop, Z. Zhang, Computing rectifying homographies for stereo vision,in: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, Vol. 1, 1999, pp. 125–131. • J. Mallon, P. F. Whelan: Projective rectification from the fundamental matrix. Image Vision Comput. 23(7): 643-650 (2005)

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