Physics-Informed Boundary Integral Networks (PIBI-Nets): A Data-Driven Approach for Solving Partial Differential Equations
- URL: http://arxiv.org/abs/2308.09571v3
- Date: Wed, 3 Jul 2024 20:31:06 GMT
- Title: Physics-Informed Boundary Integral Networks (PIBI-Nets): A Data-Driven Approach for Solving Partial Differential Equations
- Authors: Monika Nagy-Huber, Volker Roth,
- Abstract summary: Partial differential equations (PDEs) are widely used to describe relevant phenomena in dynamical systems.
In high-dimensional settings, PINNs often suffer from computational problems because they require dense collocation points over the entire computational domain.
We present Physics-Informed Boundary Networks (PIBI-Nets) as a data-driven approach for solving PDEs in one dimension less than the original problem space.
- Score: 1.6435014180036467
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Partial differential equations (PDEs) are widely used to describe relevant phenomena in dynamical systems. In real-world applications, we commonly need to combine formal PDE models with (potentially noisy) observations. This is especially relevant in settings where we lack information about boundary or initial conditions, or where we need to identify unknown model parameters. In recent years, Physics-Informed Neural Networks (PINNs) have become a popular tool for this kind of problems. In high-dimensional settings, however, PINNs often suffer from computational problems because they usually require dense collocation points over the entire computational domain. To address this problem, we present Physics-Informed Boundary Integral Networks (PIBI-Nets) as a data-driven approach for solving PDEs in one dimension less than the original problem space. PIBI-Nets only require points at the computational domain boundary, while still achieving highly accurate results. Moreover, PIBI-Nets clearly outperform PINNs in several practical settings. Exploiting elementary properties of fundamental solutions of linear differential operators, we present a principled and simple way to handle point sources in inverse problems. We demonstrate the excellent performance of PIBI- Nets for the Laplace and Poisson equations, both on artificial datasets and within a real-world application concerning the reconstruction of groundwater flows.
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) - A physics-informed neural network framework for modeling obstacle-related equations [3.687313790402688]
Physics-informed neural networks (PINNs) are an attractive tool for solving partial differential equations based on sparse and noisy data.
Here we extend PINNs to solve obstacle-related PDEs which present a great computational challenge.
The performance of the proposed PINNs is demonstrated in multiple scenarios for linear and nonlinear PDEs subject to regular and irregular obstacles.
arXiv Detail & Related papers (2023-04-07T09:22:28Z) - Deep NURBS -- Admissible Physics-informed Neural Networks [0.0]
We propose a new numerical scheme for physics-informed neural networks (PINNs) that enables precise and inexpensive solution for partial differential equations (PDEs)
The proposed approach combines admissible NURBS parametrizations required to define the physical domain and the Dirichlet boundary conditions with a PINN solver.
arXiv Detail & Related papers (2022-10-25T10:35:45Z) - Physics-Aware Neural Networks for Boundary Layer Linear Problems [0.0]
Physics-Informed Neural Networks (PINNs) approximate the solution of general partial differential equations (PDEs) by adding them in some form as terms of the loss/cost of a Neural Network.
This paper explores PINNs for linear PDEs whose solutions may present one or more boundary layers.
arXiv Detail & Related papers (2022-07-15T21:15:06Z) - Learning to Solve PDE-constrained Inverse Problems with Graph Networks [51.89325993156204]
In many application domains across science and engineering, we are interested in solving inverse problems with constraints defined by a partial differential equation (PDE)
Here we explore GNNs to solve such PDE-constrained inverse problems.
We demonstrate computational speedups of up to 90x using GNNs compared to principled solvers.
arXiv Detail & Related papers (2022-06-01T18:48:01Z) - 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-Informed Neural Operator for Learning Partial Differential
Equations [55.406540167010014]
PINO is the first hybrid approach incorporating data and PDE constraints at different resolutions to learn the operator.
The resulting PINO model can accurately approximate the ground-truth solution operator for many popular PDE families.
arXiv Detail & Related papers (2021-11-06T03:41:34Z) - Characterizing possible failure modes in physics-informed neural
networks [55.83255669840384]
Recent work in scientific machine learning has developed so-called physics-informed neural network (PINN) models.
We demonstrate that, while existing PINN methodologies can learn good models for relatively trivial problems, they can easily fail to learn relevant physical phenomena even for simple PDEs.
We show that these possible failure modes are not due to the lack of expressivity in the NN architecture, but that the PINN's setup makes the loss landscape very hard to optimize.
arXiv Detail & Related papers (2021-09-02T16:06:45Z) - PhyCRNet: Physics-informed Convolutional-Recurrent Network for Solving
Spatiotemporal PDEs [8.220908558735884]
Partial differential equations (PDEs) play a fundamental role in modeling and simulating problems across a wide range of disciplines.
Recent advances in deep learning have shown the great potential of physics-informed neural networks (NNs) to solve PDEs as a basis for data-driven inverse analysis.
We propose the novel physics-informed convolutional-recurrent learning architectures (PhyCRNet and PhCRyNet-s) for solving PDEs without any labeled data.
arXiv Detail & Related papers (2021-06-26T22:22:19Z) - dNNsolve: an efficient NN-based PDE solver [62.997667081978825]
We introduce dNNsolve, that makes use of dual Neural Networks to solve ODEs/PDEs.
We show that dNNsolve is capable of solving a broad range of ODEs/PDEs in 1, 2 and 3 spacetime dimensions.
arXiv Detail & Related papers (2021-03-15T19:14:41Z) - Physics informed deep learning for computational elastodynamics without
labeled data [13.084113582897965]
We present a physics-informed neural network (PINN) with mixed-variable output to model elastodynamics problems without resort to labeled data.
Results show the promise of PINN in the context of computational mechanics applications.
arXiv Detail & Related papers (2020-06-10T19:05:08Z)
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.