Yeo-Jin Yoon1, Alexander Lelidis2, Cengiz Öztireli3, Jung-Min Hwang1, Markus Gross3, Soo-Mi Choi1
1Department of Computer Science and Engineering, Sejong University, Seoul, Republic of Korea
2TU Berlin, Berlin, Germany
3Computer Graphics Laboratory, ETH Zu ̈rich Zu ̈rich, Switzerland
Geometry data in massive amounts can be generated thanks to the modern capture devices and mature geometry modeling tools. It is essential to develop the tools to analyze and utilize this big data. In this paper, we present an exploration of analyzing geometries via learning local geometry features. After extracting local geometry patches, we parameterize each patch geometry by a radial basis function based interpolation. We use the resulting coefficients as discrete representations of the patches. These are then fed into feature learning algorithms to extract the dominant components explaining the overall patch database. This simple approach allows us to handle general representations such as point clouds or meshes with noise, outliers, and missing data. We present features learned on several patch databases to illustrate the utility of such an analysis for geometry processing applications.
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