TY - GEN
T1 - CageNet
T2 - SIGGRAPH 2025 Conference Papers
AU - Edelstein, Michal
AU - Derek Liu, Hsueh Ti
AU - Ben-Chen, Mirela
N1 - Publisher Copyright:
© 2025 Copyright held by the owner/author(s).
PY - 2025/7/27
Y1 - 2025/7/27
N2 - Learning on triangle meshes has recently proven to be instrumental to a myriad of tasks, from shape classification, to segmentation, to deformation and animation, to mention just a few. While some of these applications are tackled through neural network architectures which are tailored to the application at hand, many others use generic frameworks for triangle meshes where the only customization required is the modification of the input features and the loss function. Our goal in this paper is to broaden the applicability of these generic frameworks to “wild” meshes, i.e. meshes in-the-wild which often have multiple components, non-manifold elements, disrupted connectivity, or a combination of these. We propose a configurable meta-framework based on the concept of caged geometry: Given a mesh, a cage is a single component manifold triangle mesh that envelopes it closely. Generalized barycentric coordinates map between functions on the cage, and functions on the mesh, allowing us to learn and test on a variety of data, in different applications. We demonstrate this concept by learning segmentation and skinning weights on difficult data, achieving better performance to state of the art techniques on wild meshes.
AB - Learning on triangle meshes has recently proven to be instrumental to a myriad of tasks, from shape classification, to segmentation, to deformation and animation, to mention just a few. While some of these applications are tackled through neural network architectures which are tailored to the application at hand, many others use generic frameworks for triangle meshes where the only customization required is the modification of the input features and the loss function. Our goal in this paper is to broaden the applicability of these generic frameworks to “wild” meshes, i.e. meshes in-the-wild which often have multiple components, non-manifold elements, disrupted connectivity, or a combination of these. We propose a configurable meta-framework based on the concept of caged geometry: Given a mesh, a cage is a single component manifold triangle mesh that envelopes it closely. Generalized barycentric coordinates map between functions on the cage, and functions on the mesh, allowing us to learn and test on a variety of data, in different applications. We demonstrate this concept by learning segmentation and skinning weights on difficult data, achieving better performance to state of the art techniques on wild meshes.
KW - geometric deep learning
KW - geometry processing
KW - skinning
UR - https://www.scopus.com/pages/publications/105013963656
U2 - 10.1145/3721238.3730654
DO - 10.1145/3721238.3730654
M3 - ???researchoutput.researchoutputtypes.contributiontobookanthology.conference???
AN - SCOPUS:105013963656
T3 - Proceedings - SIGGRAPH 2025 Conference Papers
BT - Proceedings - SIGGRAPH 2025 Conference Papers
A2 - Spencer, Stephen N.
Y2 - 10 August 2025 through 14 October 2025
ER -