Slinky, a helical elastic rod, is a seemingly simple structure with unusual mechanical behavior; for example, it can walk down a flight of stairs under its own weight. Taking the Slinky as a test-case, we propose a physics-informed deep learning approach for building reduced-order models of physical systems. The approach introduces a Euclidean symmetric neural network (ESNN) architecture that is trained under the neural ordinary differential equation framework to learn the 2D latent dynamics from the motion trajectory of a reduced-order representation of the 3D Slinky. The ESNN implements a physics-guided architecture that simultaneously preserves energy invariance and force equivariance on Euclidean transformations of the input, including ...
Neural Ordinary Differential Equations model dynamical systems with ODEs learned by neural networks....
We propose Geometric Neural Parametric Models (GNPM), a learned parametric model that takes into acc...
We explore training deep neural network models in conjunction with physical simulations via partial ...
We present e3nn, a generalized framework for creating E(3) equivariant trainable functions, also kno...
The goal of this paper is to determine the laws of observed trajectories assuming that there is a me...
We train a neural network model to predict the full phase space evolution of cosmological N-body sim...
Over the last decade, deep learning methods have achieved success in diverse domains, becoming one o...
From designing architected materials to connecting mechanical behavior across scales, computational ...
Thesis (Ph.D.)--University of Washington, 2022Nonlinear dynamical systems are ubiquitous in many fie...
We present an end-to-end framework to learn partial differential equations that brings together init...
Recent approaches for modelling dynamics of physical systems with neural networks enforce Lagrangian...
Deep learning has achieved astonishing results on many tasks with large amounts of data and generali...
Recently, there has been an increasing interest in modelling and computation of physical systems wit...
Deep learning has achieved astonishing results on many tasks with large amounts of data and general...
Equivariant Graph neural Networks (EGNs) are powerful in characterizing the dynamics of multi-body p...
Neural Ordinary Differential Equations model dynamical systems with ODEs learned by neural networks....
We propose Geometric Neural Parametric Models (GNPM), a learned parametric model that takes into acc...
We explore training deep neural network models in conjunction with physical simulations via partial ...
We present e3nn, a generalized framework for creating E(3) equivariant trainable functions, also kno...
The goal of this paper is to determine the laws of observed trajectories assuming that there is a me...
We train a neural network model to predict the full phase space evolution of cosmological N-body sim...
Over the last decade, deep learning methods have achieved success in diverse domains, becoming one o...
From designing architected materials to connecting mechanical behavior across scales, computational ...
Thesis (Ph.D.)--University of Washington, 2022Nonlinear dynamical systems are ubiquitous in many fie...
We present an end-to-end framework to learn partial differential equations that brings together init...
Recent approaches for modelling dynamics of physical systems with neural networks enforce Lagrangian...
Deep learning has achieved astonishing results on many tasks with large amounts of data and generali...
Recently, there has been an increasing interest in modelling and computation of physical systems wit...
Deep learning has achieved astonishing results on many tasks with large amounts of data and general...
Equivariant Graph neural Networks (EGNs) are powerful in characterizing the dynamics of multi-body p...
Neural Ordinary Differential Equations model dynamical systems with ODEs learned by neural networks....
We propose Geometric Neural Parametric Models (GNPM), a learned parametric model that takes into acc...
We explore training deep neural network models in conjunction with physical simulations via partial ...