We propose Geometric Neural Parametric Models (GNPM), a learned parametric model that takes into account the local structure of data to learn disentangled shape and pose latent spaces of 4D dynamics, using a geometric-aware architecture on point clouds. Temporally consistent 3D deformations are estimated without the need for dense correspondences at training time, by exploiting cycle consistency. Besides its ability to learn dense correspondences, GNPMs also enable latent-space manipulations such as interpolation and shape/pose transfer. We evaluate GNPMs on various datasets of clothed humans, and show that it achieves comparable performance to state-of-the-art methods that require dense correspondences during training.Comment: 10 pages, 8 ...
Fitting parametric models of human bodies, hands or faces to sparse input signals in an accurate, ro...
Deep learning has achieved tremendous progress and success in processing images and natural language...
We develop data-driven methods incorporating geometric and topological information to learn parsimon...
Efficient representation of articulated objects such as human bodies is an important problem in comp...
We propose a novel optimization-based paradigm for 3D human model fitting on images and scans. In co...
Solving geometric tasks involving point clouds by using machine learning is a challenging problem. S...
Generative models for 3D geometric data arise in many important applications in 3D computer vision a...
In this work, we present a new method for 3D face reconstruction from sparse-view RGB images. Unlike...
In recent years, there has been a surge in the availability of 3D sensors, leading to an exponential...
We introduce NeuralMLS, a space-based deformation technique, guided by a set of displaced control po...
We present a novel 3D mapping method leveraging the recent progress in neural implicit representatio...
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We propose a novel 3D morphable model for complete human heads based on hybrid neural fields. At the...
We propose an unsupervised method for 3D geometry-aware representation learning of articulated objec...
In many contexts, simpler models are preferable to more complex models and the control of this model...
Fitting parametric models of human bodies, hands or faces to sparse input signals in an accurate, ro...
Deep learning has achieved tremendous progress and success in processing images and natural language...
We develop data-driven methods incorporating geometric and topological information to learn parsimon...
Efficient representation of articulated objects such as human bodies is an important problem in comp...
We propose a novel optimization-based paradigm for 3D human model fitting on images and scans. In co...
Solving geometric tasks involving point clouds by using machine learning is a challenging problem. S...
Generative models for 3D geometric data arise in many important applications in 3D computer vision a...
In this work, we present a new method for 3D face reconstruction from sparse-view RGB images. Unlike...
In recent years, there has been a surge in the availability of 3D sensors, leading to an exponential...
We introduce NeuralMLS, a space-based deformation technique, guided by a set of displaced control po...
We present a novel 3D mapping method leveraging the recent progress in neural implicit representatio...
We introduce a novel approach for rendering static and dynamic 3D neural signed distance functions (...
We propose a novel 3D morphable model for complete human heads based on hybrid neural fields. At the...
We propose an unsupervised method for 3D geometry-aware representation learning of articulated objec...
In many contexts, simpler models are preferable to more complex models and the control of this model...
Fitting parametric models of human bodies, hands or faces to sparse input signals in an accurate, ro...
Deep learning has achieved tremendous progress and success in processing images and natural language...
We develop data-driven methods incorporating geometric and topological information to learn parsimon...