Line Enhancement and Completion via Linear Left Invariant Scale Spaces on SE(2)

From an image we construct an invertible orientation score, which provides an overview of local orientations in an image. This orientation score is a function on the group SE (2) of both positions and orientations. It allows us to diffuse along multiple local line segments in an image. The transformation from image to orientation score amounts to convolutions with an oriented kernel rotated at multiple angles. Under conditions on the oriented kernel the transform between image and orientation score is unitary. This allows us to relate operators on images to operators on orientation scores in a robust way such that we can deal with crossing lines and orientation uncertainty. To obtain reasonable Euclidean invariant image processing the operator on the orientation score must be both left invariant and non-linear. Therefore we consider non-linear operators on orientation scores which amount to direct products of linear left-invariant scale spaces on SE (2). These linear left-invariant scale spaces correspond to well-known stochastic processes on SE (2) for line completion and line enhancement and are given by group convolution with the corresponding Green's functions. We provide the exact Green's functions and approximations, which we use together with invertible orientation scores for automatic line enhancement and completion.

[1]  Knut-Andreas Lie,et al.  Scale Space and Variational Methods in Computer Vision, Second International Conference, SSVM 2009, Voss, Norway, June 1-5, 2009. Proceedings , 2009, SSVM.

[2]  Andreas Rieder,et al.  Wavelets: Theory and Applications , 1997 .

[3]  E. Franken Enhancement of crossing elongated structures in images , 2008 .

[4]  Peter Johansen,et al.  Gaussian Scale-Space Theory , 1997, Computational Imaging and Vision.

[5]  Mi-Suen Lee,et al.  A Computational Framework for Segmentation and Grouping , 2000 .

[6]  Remco Duits Perceptual organization in image analysis : a mathematical approach based on scale, orientation and curvature , 2005 .

[7]  K. Thornber,et al.  Analytic solution of stochastic completion fields , 1995, Proceedings of International Symposium on Computer Vision - ISCV.

[8]  R. Duits,et al.  Left-invariant parabolic evolutions on SE(2) and contour enhancement via invertible orientation scores. Part II: Non-linear left-invariant diffusions on invertible orientation scores , 2010 .

[9]  R. Duits,et al.  The explicit solutions of linear left-invariant second order stochastic evolution equations on the 2D-Euclidean motion group , 2007 .

[10]  D. Mumford Elastica and Computer Vision , 1994 .

[11]  Lance R. Williams,et al.  Euclidean Group Invariant Computation of Stochastic Completion Fields Using Shiftable-Twistable Functions , 2000, Journal of Mathematical Imaging and Vision.

[12]  S. Zucker,et al.  The curve indicator random field , 2001 .

[13]  A. Grossmann,et al.  Transforms associated to square integrable group representations. I. General results , 1985 .

[14]  van Ma Markus Almsick,et al.  Context models of lines and contours , 2007 .

[15]  E. Candès New Ties between Computational Harmonic Analysis and Approximation Theory , 2002 .

[16]  J. Meixner,et al.  Mathieusche Funktionen und Sphäroidfunktionen , 1954 .

[17]  Max A. Viergever,et al.  Invertible Apertured Orientation Filters in Image Analysis , 1999, International Journal of Computer Vision.

[18]  Bernhard Burgeth,et al.  Scale Spaces on Lie Groups , 2007, SSVM.

[19]  R. Duits,et al.  Left-invariant parabolic evolutions on SE(2) and contour enhancement via invertible orientation scores. Part I: Linear left-invariant diffusion equations on SE(2) , 2010 .

[20]  Remco Duits,et al.  Nonlinear Diffusion on the 2D Euclidean Motion Group , 2007, SSVM.

[21]  Giovanna Citti,et al.  A Cortical Based Model of Perceptual Completion in the Roto-Translation Space , 2006, Journal of Mathematical Imaging and Vision.