Physics-constrained Unsupervised Learning of Partial Differential
Equations using Meshes
- URL: http://arxiv.org/abs/2203.16628v1
- Date: Wed, 30 Mar 2022 19:22:56 GMT
- Title: Physics-constrained Unsupervised Learning of Partial Differential
Equations using Meshes
- Authors: Mike Y. Michelis and Robert K. Katzschmann
- Abstract summary: Graph neural networks show promise in accurately representing irregularly meshed objects and learning their dynamics.
In this work, we represent meshes naturally as graphs, process these using Graph Networks, and formulate our physics-based loss to provide an unsupervised learning framework for partial differential equations (PDE)
Our framework will enable the application of PDE solvers in interactive settings, such as model-based control of soft-body deformations.
- Score: 1.066048003460524
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Enhancing neural networks with knowledge of physical equations has become an
efficient way of solving various physics problems, from fluid flow to
electromagnetism. Graph neural networks show promise in accurately representing
irregularly meshed objects and learning their dynamics, but have so far
required supervision through large datasets. In this work, we represent meshes
naturally as graphs, process these using Graph Networks, and formulate our
physics-based loss to provide an unsupervised learning framework for partial
differential equations (PDE). We quantitatively compare our results to a
classical numerical PDE solver, and show that our computationally efficient
approach can be used as an interactive PDE solver that is adjusting boundary
conditions in real-time and remains sufficiently close to the baseline
solution. Our inherently differentiable framework will enable the application
of PDE solvers in interactive settings, such as model-based control of
soft-body deformations, or in gradient-based optimization methods that require
a fully differentiable pipeline.
Related papers
- A Stable and Scalable Method for Solving Initial Value PDEs with Neural
Networks [52.5899851000193]
We develop an ODE based IVP solver which prevents the network from getting ill-conditioned and runs in time linear in the number of parameters.
We show that current methods based on this approach suffer from two key issues.
First, following the ODE produces an uncontrolled growth in the conditioning of the problem, ultimately leading to unacceptably large numerical errors.
arXiv Detail & Related papers (2023-04-28T17:28:18Z) - Implicit Stochastic Gradient Descent for Training Physics-informed
Neural Networks [51.92362217307946]
Physics-informed neural networks (PINNs) have effectively been demonstrated in solving forward and inverse differential equation problems.
PINNs are trapped in training failures when the target functions to be approximated exhibit high-frequency or multi-scale features.
In this paper, we propose to employ implicit gradient descent (ISGD) method to train PINNs for improving the stability of training process.
arXiv Detail & Related papers (2023-03-03T08:17:47Z) - NeuralStagger: Accelerating Physics-constrained Neural PDE Solver with
Spatial-temporal Decomposition [67.46012350241969]
This paper proposes a general acceleration methodology called NeuralStagger.
It decomposing the original learning tasks into several coarser-resolution subtasks.
We demonstrate the successful application of NeuralStagger on 2D and 3D fluid dynamics simulations.
arXiv Detail & Related papers (2023-02-20T19:36:52Z) - Physics-aware deep learning framework for linear elasticity [0.0]
The paper presents an efficient and robust data-driven deep learning (DL) computational framework for linear continuum elasticity problems.
For an accurate representation of the field variables, a multi-objective loss function is proposed.
Several benchmark problems including the Airimaty solution to elasticity and the Kirchhoff-Love plate problem are solved.
arXiv Detail & Related papers (2023-02-19T20:33:32Z) - Learning differentiable solvers for systems with hard constraints [48.54197776363251]
We introduce a practical method to enforce partial differential equation (PDE) constraints for functions defined by neural networks (NNs)
We develop a differentiable PDE-constrained layer that can be incorporated into any NN architecture.
Our results show that incorporating hard constraints directly into the NN architecture achieves much lower test error when compared to training on an unconstrained objective.
arXiv Detail & Related papers (2022-07-18T15:11:43Z) - Mitigating Learning Complexity in Physics and Equality Constrained
Artificial Neural Networks [0.9137554315375919]
Physics-informed neural networks (PINNs) have been proposed to learn the solution of partial differential equations (PDE)
In PINNs, the residual form of the PDE of interest and its boundary conditions are lumped into a composite objective function as soft penalties.
Here, we show that this specific way of formulating the objective function is the source of severe limitations in the PINN approach when applied to different kinds of PDEs.
arXiv Detail & Related papers (2022-06-19T04:12:01Z) - Learning time-dependent PDE solver using Message Passing Graph Neural
Networks [0.0]
We introduce a graph neural network approach to finding efficient PDE solvers through learning using message-passing models.
We use graphs to represent PDE-data on an unstructured mesh and show that message passing graph neural networks (MPGNN) can parameterize governing equations.
We show that a recurrent graph neural network approach can find a temporal sequence of solutions to a PDE.
arXiv Detail & Related papers (2022-04-15T21:10:32Z) - Message Passing Neural PDE Solvers [60.77761603258397]
We build a neural message passing solver, replacing allally designed components in the graph with backprop-optimized neural function approximators.
We show that neural message passing solvers representationally contain some classical methods, such as finite differences, finite volumes, and WENO schemes.
We validate our method on various fluid-like flow problems, demonstrating fast, stable, and accurate performance across different domain topologies, equation parameters, discretizations, etc., in 1D and 2D.
arXiv Detail & Related papers (2022-02-07T17:47:46Z) - Physics and Equality Constrained Artificial Neural Networks: Application
to Partial Differential Equations [1.370633147306388]
Physics-informed neural networks (PINNs) have been proposed to learn the solution of partial differential equations (PDE)
Here, we show that this specific way of formulating the objective function is the source of severe limitations in the PINN approach.
We propose a versatile framework that can tackle both inverse and forward problems.
arXiv Detail & Related papers (2021-09-30T05:55:35Z) - Multipole Graph Neural Operator for Parametric Partial Differential
Equations [57.90284928158383]
One of the main challenges in using deep learning-based methods for simulating physical systems is formulating physics-based data.
We propose a novel multi-level graph neural network framework that captures interaction at all ranges with only linear complexity.
Experiments confirm our multi-graph network learns discretization-invariant solution operators to PDEs and can be evaluated in linear time.
arXiv Detail & Related papers (2020-06-16T21:56:22Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.