Neural varifolds: an aggregate representation for quantifying the geometry of point clouds
Neural varifolds: an aggregate representation for quantifying the geometry of point clouds
Point clouds are popular 3D representations for real-life objects (such as in LiDAR and Kinect) due to their detailed and compact representation of surface-based geometry. Recent approaches characterise the geometry of point clouds by bringing deep learning based techniques together with geometric fidelity metrics such as optimal transportation costs (e.g., Chamfer and Wasserstein metrics). In this paper, we propose a new surface geometry characterisation within this realm, namely a neural varifold representation of point clouds. Here the surface is represented as a measure/distribution over both point positions and tangent spaces of point clouds. The varifold representation quantifies not only the surface geometry of point clouds through the manifold-based discrimination, but also subtle geometric consistencies on the surface due to the combined product space. This study proposes neural varifold algorithms to compute the varifold norm between two point clouds using neural networks on point clouds and their neural tangent kernel representations. The proposed neural varifold is evaluated on three different sought-after tasks -- shape matching, few-shot shape classification and shape reconstruction. Detailed evaluation and comparison to the state-of-the-art methods demonstrate that the proposed versatile neural varifold is superior in shape matching and few-shot shape classification, and is competitive for shape reconstruction.
cs.CV, cs.AI
Lee, Juheon
bcc7dd3e-6eef-418a-a735-8bb38d51476f
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
Schönlieb, Carola-Bibian
de54aed2-a607-4b29-a9d0-8af779b07277
Masnou, Simon
d114f8bb-5ddc-46e1-a35f-302c7fa778a2
5 July 2024
Lee, Juheon
bcc7dd3e-6eef-418a-a735-8bb38d51476f
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
Schönlieb, Carola-Bibian
de54aed2-a607-4b29-a9d0-8af779b07277
Masnou, Simon
d114f8bb-5ddc-46e1-a35f-302c7fa778a2
[Unknown type: UNSPECIFIED]
Abstract
Point clouds are popular 3D representations for real-life objects (such as in LiDAR and Kinect) due to their detailed and compact representation of surface-based geometry. Recent approaches characterise the geometry of point clouds by bringing deep learning based techniques together with geometric fidelity metrics such as optimal transportation costs (e.g., Chamfer and Wasserstein metrics). In this paper, we propose a new surface geometry characterisation within this realm, namely a neural varifold representation of point clouds. Here the surface is represented as a measure/distribution over both point positions and tangent spaces of point clouds. The varifold representation quantifies not only the surface geometry of point clouds through the manifold-based discrimination, but also subtle geometric consistencies on the surface due to the combined product space. This study proposes neural varifold algorithms to compute the varifold norm between two point clouds using neural networks on point clouds and their neural tangent kernel representations. The proposed neural varifold is evaluated on three different sought-after tasks -- shape matching, few-shot shape classification and shape reconstruction. Detailed evaluation and comparison to the state-of-the-art methods demonstrate that the proposed versatile neural varifold is superior in shape matching and few-shot shape classification, and is competitive for shape reconstruction.
Text
2407.04844v1
- Author's Original
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Published date: 5 July 2024
Additional Information:
The first author, Juheon Lee, is an unaffiliated, independent researcher. This work is a personal endeavor, unrelated to his current job
Keywords:
cs.CV, cs.AI
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Local EPrints ID: 498024
URI: http://eprints.soton.ac.uk/id/eprint/498024
PURE UUID: 601eef42-15d3-4a97-ba23-89f732ee7c57
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Date deposited: 06 Feb 2025 17:33
Last modified: 07 Feb 2025 03:02
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Contributors
Author:
Juheon Lee
Author:
Xiaohao Cai
Author:
Carola-Bibian Schönlieb
Author:
Simon Masnou
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