TY - GEN
T1 - Multi-directional geodesic neural networks via equivariant convolution
AU - Poulenard, Adrien
AU - Ovsjanikov, Maks
N1 - Publisher Copyright:
© 2018 Copyright held by the owner/author(s). Publication rights licensed to the Association for Computing Machinery.
PY - 2018/12/4
Y1 - 2018/12/4
N2 - We propose a novel approach for performing convolution of signals on curved surfaces and show its utility in a variety of geometric deep learning applications. Key to our construction is the notion of directional functions defined on the surface, which extend the classic real-valued signals and which can be naturally convolved with with real-valued template functions. As a result, rather than trying to fix a canonical orientation or only keeping the maximal response across all alignments of a 2D template at every point of the surface, as done in previous works, we show how information across all rotations can be kept across different layers of the neural network. Our construction, which we call multi-directional geodesic convolution, or directional convolution for short, allows, in particular, to propagate and relate directional information across layers and thus different regions on the shape. We first define directional convolution in the continuous setting, prove its key properties and then show how it can be implemented in practice, for shapes represented as triangle meshes. We evaluate directional convolution in a wide variety of learning scenarios ranging from classification of signals on surfaces, to shape segmentation and shape matching, where we show a significant improvement over several baselines.
AB - We propose a novel approach for performing convolution of signals on curved surfaces and show its utility in a variety of geometric deep learning applications. Key to our construction is the notion of directional functions defined on the surface, which extend the classic real-valued signals and which can be naturally convolved with with real-valued template functions. As a result, rather than trying to fix a canonical orientation or only keeping the maximal response across all alignments of a 2D template at every point of the surface, as done in previous works, we show how information across all rotations can be kept across different layers of the neural network. Our construction, which we call multi-directional geodesic convolution, or directional convolution for short, allows, in particular, to propagate and relate directional information across layers and thus different regions on the shape. We first define directional convolution in the continuous setting, prove its key properties and then show how it can be implemented in practice, for shapes represented as triangle meshes. We evaluate directional convolution in a wide variety of learning scenarios ranging from classification of signals on surfaces, to shape segmentation and shape matching, where we show a significant improvement over several baselines.
KW - Convolution
KW - Geometric Deep Learning
KW - Parallel Transport
KW - Rotation Equivariance
UR - https://www.scopus.com/pages/publications/85066092662
U2 - 10.1145/3272127.3275102
DO - 10.1145/3272127.3275102
M3 - Conference contribution
AN - SCOPUS:85066092662
T3 - SIGGRAPH Asia 2018 Technical Papers, SIGGRAPH Asia 2018
BT - SIGGRAPH Asia 2018 Technical Papers, SIGGRAPH Asia 2018
PB - Association for Computing Machinery, Inc
T2 - SIGGRAPH Asia 2018 Technical Papers - International Conference on Computer Graphics and Interactive Techniques, SIGGRAPH Asia 2018
Y2 - 4 December 2018 through 7 December 2018
ER -