The Hamilton-Jacobi skeleton

The Hamilton-Jacobi skeleton

The eikonal equation and variants of it are of significant interest for problems in computer vision and image processing. It is the basis for continuous versions of mathematical morphology, stereo, shape-from-shading and for recent dynamic theories of shape. Its numerical simulation can be delicate,...

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Bibliographic Details
Published in:Proceedings of the Seventh IEEE International Conference on Computer Vision Vol. 2; pp. 828 - 834 vol.2
Main Authors: Siddiqi, K., Bouix, S., Tannenbaum, A., Zucker, S.W.
Format: Conference Proceeding
Language:English
Published: Los Alamitos CA IEEE 1999
IEEE Computer Society
Subjects:
Applied sciences
Artificial intelligence
Canonical formalism, lagrangians, and variational principles
Classical general relativity
Computer science; control theory; systems
Computer vision
Electric shock
Equations
Exact sciences and technology
General relativity and gravitation
Image processing
Level set
Morphology
Numerical simulation
Pattern recognition. Digital image processing. Computational geometry
Physics
Shape
Skeleton
Stereo vision
Computer vision
Hamilton Jacobi equation
Image processing
Hamilton equation
Variational principle
Numerical simulation
Hamiltonian system
Three dimensional shape
Canonical equation
Mathematical morphology
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Summary:The eikonal equation and variants of it are of significant interest for problems in computer vision and image processing. It is the basis for continuous versions of mathematical morphology, stereo, shape-from-shading and for recent dynamic theories of shape. Its numerical simulation can be delicate, owing to the formation of singularities in the evolving front, and is typically based or, level set methods. However there are more classical approaches rooted in Hamiltonian physics, which have received little consideration in computer vision. In this paper we first introduce a new algorithm for simulating the eikonal equation, which offers a number of computational and conceptual advantages over the earlier methods when it comes to shock tracking. Next, we introduce a very efficient algorithm for shock detection, where the key idea is to measure the net outward flux of a vector field per unit volume, and to detect locations where a conservation of energy principle is violated. We illustrate the approach with several numerical examples including skeletons of complex 2D and 3D shapes.
ISBN:9780769501642
0769501648
DOI:10.1109/ICCV.1999.790307