Reeb graph

A Reeb graph (named after Georges Reeb) is a mathematical object reflecting the evolution of the level sets of a real-valued function on a manifold.^[1] Originally introduced by G.M. Adelson-Velskii and A.S. Kronrod and applied to analysis of Hilbert's thirteenth problem.^[2] Proposed by G. Reeb as a tool in Morse theory,^[3] Reeb graphs found a wide variety of applications in computational geometry and computer graphics, including computer aided geometric design, topology-based shape matching,^[4] topological simplification and cleaning, surface segmentation and parametrization, efficient computation of level sets, and geometrical thermodynamics.^[5] In a special case of a function on a flat space, the Reeb graph forms a polytree and is also called a contour tree.^[6]

Formal definition

Given a topological space X and a continuous function f: X → R, define an equivalence relation ∼ on X where p∼q whenever p and q belong to the same connected component of a single level set f⁻¹(c) for some real c. The Reeb graph is the quotient space X /∼ endowed with the quotient topology.

Description for Morse functions

If f is a Morse function with distinct critical values, the Reeb graph can be described more explicitly. Its nodes, or vertices, correspond to the critical level sets f⁻¹(c). The pattern in which the arcs, or edges, meet at the nodes/vertices reflects the change in topology of the level set f⁻¹(t) as t passes through the critical value c. For example, if c is a minimum or a maximum of f, a component is created or destroyed; consequently, an arc originates or terminates at the corresponding node, which has degree 1. If c is a saddle point of index 1 and two components of f⁻¹(t) merge at t = c as t increases, the corresponding vertex of the Reeb graph has degree 3 and looks like the letter "Y"; the same reasoning applies if the index of c is dim X−1 and a component of f⁻¹(c) splits into two.

References

^ Harish Doraiswamy, Vijay Natarajan, Efficient algorithms for computing Reeb graphs, Computational Geometry 42 (2009) 606–616
^ G. M. Adelson-Velskii, A. S. Kronrod, About level sets of continuous functions with partial derivatives, Dokl. Akad. Nauk SSSR, 49 (4) (1945), pp. 239–241.
^ G. Reeb, Sur les points singuliers d’une forme de Pfaff complètement intégrable ou d’une fonction numérique, C. R. Acad. Sci. Paris 222 (1946) 847–849
^ Tung, Tony; Schmitt, Francis (2005). "The Augmented Multiresolution Reeb Graph Approach for Content-Based Retrieval of 3D Shapes". International Journal of Shape Modeling (IJSM). 11 (1): 91–120.
^ A.N. Gorban, Thermodynamic Tree: The Space of Admissible Paths, SIAM Journal on Applied Dynamical Systems 12(1) (2013), 246-278.
^ Carr, Hamish; Snoeyink, Jack; Axen, Ulrike (2000), "Computing contour trees in all dimensions", Proc. 11th ACM-SIAM Symposium on Discrete Algorithms (SODA 2000), pp. 918–926.

[1] Harish Doraiswamy, Vijay Natarajan, Efficient algorithms for computing Reeb graphs, Computational Geometry 42 (2009) 606–616

[2] G. M. Adelson-Velskii, A. S. Kronrod, About level sets of continuous functions with partial derivatives, Dokl. Akad. Nauk SSSR, 49 (4) (1945), pp. 239–241.

[3] G. Reeb, Sur les points singuliers d’une forme de Pfaff complètement intégrable ou d’une fonction numérique, C. R. Acad. Sci. Paris 222 (1946) 847–849

[4] Tung, Tony; Schmitt, Francis (2005). "The Augmented Multiresolution Reeb Graph Approach for Content-Based Retrieval of 3D Shapes". International Journal of Shape Modeling (IJSM). 11 (1): 91–120.

[5] A.N. Gorban, Thermodynamic Tree: The Space of Admissible Paths, SIAM Journal on Applied Dynamical Systems 12(1) (2013), 246-278.

[6] Carr, Hamish; Snoeyink, Jack; Axen, Ulrike (2000), "Computing contour trees in all dimensions", Proc. 11th ACM-SIAM Symposium on Discrete Algorithms (SODA 2000), pp. 918–926.

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