Rotation invariance is a crucial property for 3D
object classification, which is still a challenging task. State-of-
the-art deep learning-based works require a massive amount
of data augmentation to tackle this problem. This is however
inefficient and classification accuracy suffers a sharp drop
in experiments with arbitrary rotations. We introduce a new
descriptor that can globally and locally capture the surface
geometry properties and is based on a combination of spher-
ical harmonics energy and point feature representation. The
proposed descriptor is proven to fulfill the rotation-invariant
property. A limited bandwidth spherical harmonics energy
descriptor globally describes a 3D shape and its rotation-
invariant property is proven by utilizing the properties of
a Wigner D-matrix, while the point feature representation
captures the local features with a KNN to build the con-
nection to its neighborhood. We propose a new network
structure by extending PointNet++ with several adaptations
that can hierarchically and efficiently exploit local rotation-
invariant features. Extensive experimental results show that
our proposed method dramatically outperforms most state-of-
the-art approaches on standard rotation-augmented 3D object
classification benchmarks as well as in robustness experiments
on point perturbation, point density, and partial point clouds.
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Rotation invariance is a crucial property for 3D
object classification, which is still a challenging task. State-of-
the-art deep learning-based works require a massive amount
of data augmentation to tackle this problem. This is however
inefficient and classification accuracy suffers a sharp drop
in experiments with arbitrary rotations. We introduce a new
descriptor that can globally and locally capture the surface
geometry properties and is based on a combination of spher-
ical harmonic...
»
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