We present a new approach to unsupervised shape correspondence learning between pairs of point clouds. We make the first attempt to adapt the classical locally linear embedding algorithm (LLE) -- originally designed for nonlinear dimensionality reduction -- for shape correspondence. The key idea is to find dense correspondences between shapes by first obtaining high-dimensional neighborhood-preserving embeddings of low-dimensional point clouds and subsequently aligning the source and target embeddings using locally linear transformations. We demonstrate that learning the embedding using a new LLE-inspired point cloud reconstruction objective results in accurate shape correspondences. More specifically, the approach comprises an end-to-end l...
International audienceWe present a robust method to find region-level correspondences between shapes...
Roweis ST, Lawrence LK. Nonlinear Dimensionality Reduction by Locally Linear Embedding. Science. 200...
International audienceIn this work, we present a novel learning-based framework that combines the lo...
International audienceWe present a novel method for computing correspondences across 3D shapes using...
We introduce the first completely unsupervised correspondence learning approach for deformable 3D sh...
This paper provides a novel framework that learns canonical embeddings for non-rigid shape matching....
Many innovative applications require establishing correspondences among 3D geometric objects. Howeve...
International audienceIn this paper, we propose a fully differentiable pipeline for estimating accur...
International audienceWe present Neural Correspondence Prior (NCP), a new paradigm for computing cor...
Shape correspondence from 3D deformation learning has attracted appealing academy interests recently...
In this work, we present a novel learning-based framework that combines the local accuracy of contra...
International audienceIn this paper we propose a method for matching articulated shapes represented ...
The problem of dimensionality reduction arises in many fields of information processing, including m...
International audienceWe present a robust method to find region-level correspondences between shapes...
Roweis ST, Lawrence LK. Nonlinear Dimensionality Reduction by Locally Linear Embedding. Science. 200...
International audienceIn this work, we present a novel learning-based framework that combines the lo...
International audienceWe present a novel method for computing correspondences across 3D shapes using...
We introduce the first completely unsupervised correspondence learning approach for deformable 3D sh...
This paper provides a novel framework that learns canonical embeddings for non-rigid shape matching....
Many innovative applications require establishing correspondences among 3D geometric objects. Howeve...
International audienceIn this paper, we propose a fully differentiable pipeline for estimating accur...
International audienceWe present Neural Correspondence Prior (NCP), a new paradigm for computing cor...
Shape correspondence from 3D deformation learning has attracted appealing academy interests recently...
In this work, we present a novel learning-based framework that combines the local accuracy of contra...
International audienceIn this paper we propose a method for matching articulated shapes represented ...
The problem of dimensionality reduction arises in many fields of information processing, including m...
International audienceWe present a robust method to find region-level correspondences between shapes...
Roweis ST, Lawrence LK. Nonlinear Dimensionality Reduction by Locally Linear Embedding. Science. 200...
International audienceIn this work, we present a novel learning-based framework that combines the lo...