Data over non-Euclidean manifolds, often discretized as surface meshes, naturally arise in computer graphics and biological and physical systems. In particular, solutions to partial differential equations (PDEs) over manifolds depend critically on the underlying geometry. While graph neural networks have been successfully applied to PDEs, they do not incorporate surface geometry and do not consider local gauge symmetries of the manifold. Alternatively, recent works on gauge equivariant convolutional and attentional architectures on meshes leverage the underlying geometry but underperform in modeling surface PDEs with complex nonlinear dynamics. To address these issues, we introduce a new gauge equivariant architecture using nonlinear messag...
When training overparameterized deep networks for classification tasks, it has been widely observed ...
Solving geometric tasks involving point clouds by using machine learning is a challenging problem. S...
We propose a novel deep learning (DL) approach to solve one-dimensional non-linear elliptic, parabol...
Equivariant Graph neural Networks (EGNs) are powerful in characterizing the dynamics of multi-body p...
The automated segmentation of cortical areas has been a long-standing challenge in medical image ana...
We develop data-driven methods incorporating geometric and topological information to learn parsimon...
We introduce an approach for solving PDEs over manifolds using physics informed neural networks whos...
Solving partial differential equations is difficult. Recently proposed neural resolution-invariant m...
We present a PDE-based framework that generalizes Group equivariant Convolutional Neural Networks (G...
Manifolds discovered by machine learning models provide a compact representation of the underlying d...
Group equivariance (e.g. SE(3) equivariance) is a critical physical symmetry in science, from classi...
We propose Geometric Neural Parametric Models (GNPM), a learned parametric model that takes into acc...
We present e3nn, a generalized framework for creating E(3) equivariant trainable functions, also kno...
We introduce in this paper new, efficient numerical methods based on neural networks for the approxi...
The principle of equivariance to symmetry transformations enables a theoretically grounded approach ...
When training overparameterized deep networks for classification tasks, it has been widely observed ...
Solving geometric tasks involving point clouds by using machine learning is a challenging problem. S...
We propose a novel deep learning (DL) approach to solve one-dimensional non-linear elliptic, parabol...
Equivariant Graph neural Networks (EGNs) are powerful in characterizing the dynamics of multi-body p...
The automated segmentation of cortical areas has been a long-standing challenge in medical image ana...
We develop data-driven methods incorporating geometric and topological information to learn parsimon...
We introduce an approach for solving PDEs over manifolds using physics informed neural networks whos...
Solving partial differential equations is difficult. Recently proposed neural resolution-invariant m...
We present a PDE-based framework that generalizes Group equivariant Convolutional Neural Networks (G...
Manifolds discovered by machine learning models provide a compact representation of the underlying d...
Group equivariance (e.g. SE(3) equivariance) is a critical physical symmetry in science, from classi...
We propose Geometric Neural Parametric Models (GNPM), a learned parametric model that takes into acc...
We present e3nn, a generalized framework for creating E(3) equivariant trainable functions, also kno...
We introduce in this paper new, efficient numerical methods based on neural networks for the approxi...
The principle of equivariance to symmetry transformations enables a theoretically grounded approach ...
When training overparameterized deep networks for classification tasks, it has been widely observed ...
Solving geometric tasks involving point clouds by using machine learning is a challenging problem. S...
We propose a novel deep learning (DL) approach to solve one-dimensional non-linear elliptic, parabol...