Abstract:
We introduce a computational framework for discovering regular or repeated geometric structures in 3D shapes. We describe and classify possible regular structures and present an effective algorithm for detecting such repeated geometric patterns in point- or meshbased models. Our method assumes no prior knowledge of the geometry or spatial location of the individual elements that define the pattern. Structure discovery is made possible by a careful analysis of pairwise similarity transformations that reveals prominent lattice structures in a suitable model of transformation space. We introduce an optimization method for detecting such uniform grids specifically designed to deal with outliers and missing elements. This yields a robust algorithm that successfully discovers complex regular structures amidst clutter, noise, and missing geometry. The accuracy of the extracted generating transformations is further improved using a novel simultaneous registration method in the spatial domain. We demonstrate the effectiveness of our algorithm on a variety of examples and show applications to compression, model repair, and geometry synthesis.
Bibtex:
@article{pauly-2008-sr, author = "M. Pauly and N. J. Mitra and J. Wallner and H. Pottmann and L. Guibas", title = "Discovering Structural Regularity in {3D} Geometry", journal = "ACM Trans. Graphics", volume = "27", number = "3", note = "Proc.\ SIGGRAPH", year = "2008", }
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