Optimal Interpolatory Wavelets Transform for Multiresolution Triangular Meshes
Chong Zhao, Hanqiu Sun
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DOI: 10.4236/am.2011.23044   PDF    HTML     5,291 Downloads   9,691 Views   Citations

Abstract

In recent years, several matrix-valued subdivisions have been proposed for triangular meshes. The ma-trix-valued subdivisions can simulate and extend the traditional scalar-valued subdivision, such as loop and subdivision. In this paper, we study how to construct the matrix-valued subdivision wavelets, and propose the novel biorthogonal wavelet based on matrix-valued subdivisions on multiresolution triangular meshes. The new wavelets transform not only inherits the advantages of subdivision, but also offers more resolutions of complex models. Based on the matrix-valued wavelets proposed, we further optimize the wavelets transform for interactive modeling and visualization applications, and develop the efficient interpolatory loop subdivision wavelets transform. The transform simplifies the computation, and reduces the memory usage of matrix-valued wavelets transform. Our experiments showed that the novel wavelets transform is sufficiently stable, and performs well for noise reduction and fitting quality especially for multiresolution semi-regular triangular meshes.

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C. Zhao and H. Sun, "Optimal Interpolatory Wavelets Transform for Multiresolution Triangular Meshes," Applied Mathematics, Vol. 2 No. 3, 2011, pp. 369-378. doi: 10.4236/am.2011.23044.

Conflicts of Interest

The authors declare no conflicts of interest.

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