Anisotropic Geometric Diffusion in Surface Processing

I
IEEE_VIS
2000
11th IEEE Visualization 2000 (VIS 2000)
Abstract - Anisotropic Geometric Diffusion in Surface Processing

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11th IEEE Visualization 2000 (VIS 2000)

Salt Lake City, UT

October 08-October 13

ISBN: 0-7803-6478-3

	ASCII Text	x
	Ulrich Clarenz, Udo Diewald, Martin Rumpf, "Anisotropic Geometric Diffusion in Surface Processing," Visualization Conference, IEEE, pp. 70, 11th IEEE Visualization 2000 (VIS 2000), 2000.

	BibTex	x
	@article{ 10.1109/VISUAL.2000.885721, author = {Ulrich Clarenz and Udo Diewald and Martin Rumpf}, title = {Anisotropic Geometric Diffusion in Surface Processing}, journal ={Visualization Conference, IEEE}, volume = {0}, year = {2000}, issn = {1070-2385}, pages = {70}, doi = {http://doi.ieeecomputersociety.org/10.1109/VISUAL.2000.885721}, publisher = {IEEE Computer Society}, address = {Los Alamitos, CA, USA}, }

	RefWorks Procite/RefMan/Endnote	x
	TY - CONF JO - Visualization Conference, IEEE TI - Anisotropic Geometric Diffusion in Surface Processing SN - 1070-2385 SP EP A1 - Ulrich Clarenz, A1 - Udo Diewald, A1 - Martin Rumpf, PY - 2000 KW - Image Processing KW - Geometric Modeling KW - Numerical Analysis VL - 0 JA - Visualization Conference, IEEE ER -

Ulrich Clarenz, University of Bonn

Udo Diewald, University of Bonn

Martin Rumpf, University of Bonn

DOI Bookmark: http://doi.ieeecomputersociety.org/10.1109/VISUAL.2000.885721

A new multiscale method in surface processing is presented here which combines the image processing methodology based on nonlinear diffusion equations and the theory of geometric evolution problems. Its aim is to smooth discretized surfaces while simultaneously enhancing geometric features such as edges and corners. This is obtained by an anisotropic curvature evolution, where time is the multiscale parameter. Here, the diffusion tensor depends on the shape operator of the evolving surface.

A spatial finite element discretization on arbitrary unstructured triangular meshes and a semi-implicit finite difference discretization in time are the building blocks of the easy to code algorithm presented here. The systems of linear equations in each timestep are solved by appropriate, preconditioned iterative solvers. Different applications underline the efficiency and flexibility of the presented type of surface processing tool.

Index Terms:

Image Processing, Geometric Modeling, Numerical Analysis

Citation:

Ulrich Clarenz, Udo Diewald, Martin Rumpf, "Anisotropic Geometric Diffusion in Surface Processing," ieee_vis, pp.70, 11th IEEE Visualization 2000 (VIS 2000), 2000

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