Toward Mesh-Invariant 3D Generative Deep Learning with Geometric Measures

Thomas Besnier; Sylvain Arguillère; Emery Pierson; Mohamed Daoudi

doi:10.1016/j.cag.2023.06.027

Toward Mesh-Invariant 3D Generative Deep Learning with Geometric Measures

Thomas Besnier
, Sylvain Arguillère
, Emery Pierson
, Mohamed Daoudi

Research output: Contribution to journal › Article › peer-review

Abstract

3D generative modeling is accelerating as the technology allowing the capture of geometric data is developing. However, the acquired data is often inconsistent, resulting in unregistered meshes or point clouds. Many generative learning algorithms require correspondence between each point when comparing the predicted shape and the target shape. We propose an architecture able to cope with different parameterizations, even during the training phase. In particular, our loss function is built upon a kernel-based metric over a representation of meshes using geometric measures such as currents and varifolds. The latter allows to implement an efficient dissimilarity measure with many desirable properties such as robustness to resampling of the mesh or point cloud. We demonstrate the efficiency and resilience of our model with a generative learning task of human faces.

Original language	English
Pages (from-to)	309-320
Number of pages	12
Journal	Computers and Graphics (Pergamon)
Volume	115
DOIs	https://doi.org/10.1016/j.cag.2023.06.027
Publication status	Published - 1 Oct 2023
Externally published	Yes

Keywords

3D generative model
Geometric measures
Unsupervised learning

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10.1016/j.cag.2023.06.027

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title = "Toward Mesh-Invariant 3D Generative Deep Learning with Geometric Measures",

abstract = "3D generative modeling is accelerating as the technology allowing the capture of geometric data is developing. However, the acquired data is often inconsistent, resulting in unregistered meshes or point clouds. Many generative learning algorithms require correspondence between each point when comparing the predicted shape and the target shape. We propose an architecture able to cope with different parameterizations, even during the training phase. In particular, our loss function is built upon a kernel-based metric over a representation of meshes using geometric measures such as currents and varifolds. The latter allows to implement an efficient dissimilarity measure with many desirable properties such as robustness to resampling of the mesh or point cloud. We demonstrate the efficiency and resilience of our model with a generative learning task of human faces.",

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AU - Besnier, Thomas

AU - Arguillère, Sylvain

AU - Pierson, Emery

AU - Daoudi, Mohamed

PY - 2023/10/1

Y1 - 2023/10/1

N2 - 3D generative modeling is accelerating as the technology allowing the capture of geometric data is developing. However, the acquired data is often inconsistent, resulting in unregistered meshes or point clouds. Many generative learning algorithms require correspondence between each point when comparing the predicted shape and the target shape. We propose an architecture able to cope with different parameterizations, even during the training phase. In particular, our loss function is built upon a kernel-based metric over a representation of meshes using geometric measures such as currents and varifolds. The latter allows to implement an efficient dissimilarity measure with many desirable properties such as robustness to resampling of the mesh or point cloud. We demonstrate the efficiency and resilience of our model with a generative learning task of human faces.

AB - 3D generative modeling is accelerating as the technology allowing the capture of geometric data is developing. However, the acquired data is often inconsistent, resulting in unregistered meshes or point clouds. Many generative learning algorithms require correspondence between each point when comparing the predicted shape and the target shape. We propose an architecture able to cope with different parameterizations, even during the training phase. In particular, our loss function is built upon a kernel-based metric over a representation of meshes using geometric measures such as currents and varifolds. The latter allows to implement an efficient dissimilarity measure with many desirable properties such as robustness to resampling of the mesh or point cloud. We demonstrate the efficiency and resilience of our model with a generative learning task of human faces.

KW - 3D generative model

KW - Geometric measures

KW - Unsupervised learning

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DO - 10.1016/j.cag.2023.06.027

M3 - Article

AN - SCOPUS:85165538638

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JO - Computers and Graphics (Pergamon)

JF - Computers and Graphics (Pergamon)

ER -

Toward Mesh-Invariant 3D Generative Deep Learning with Geometric Measures

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Keywords

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