Related papers: Solving inverse-PDE problems with physics-aware neural networks

Solving inverse-PDE problems with physics-aware neural networks

URL: http://arxiv.org/abs/2001.03608v3
Date: Wed, 18 Nov 2020 21:47:28 GMT
Title: Solving inverse-PDE problems with physics-aware neural networks
Authors: Samira Pakravan, Pouria A. Mistani, Miguel Angel Aragon-Calvo, Frederic Gibou
Abstract summary: We propose a novel framework to find unknown fields in the context of inverse problems for partial differential equations. We blend the high expressibility of deep neural networks as universal function estimators with the accuracy and reliability of existing numerical algorithms.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We propose a novel composite framework to find unknown fields in the context of inverse problems for partial differential equations (PDEs). We blend the high expressibility of deep neural networks as universal function estimators with the accuracy and reliability of existing numerical algorithms for partial differential equations as custom layers in semantic autoencoders. Our design brings together techniques of computational mathematics, machine learning and pattern recognition under one umbrella to incorporate domain-specific knowledge and physical constraints to discover the underlying hidden fields. The network is explicitly aware of the governing physics through a hard-coded PDE solver layer in contrast to most existing methods that incorporate the governing equations in the loss function or rely on trainable convolutional layers to discover proper discretizations from data. This subsequently focuses the computational load to only the discovery of the hidden fields and therefore is more data efficient. We call this architecture Blended inverse-PDE networks (hereby dubbed BiPDE networks) and demonstrate its applicability for recovering the variable diffusion coefficient in Poisson problems in one and two spatial dimensions, as well as the diffusion coefficient in the time-dependent and nonlinear Burgers' equation in one dimension. We also show that this approach is robust to noise.

Related papers

Separable DeepONet: Breaking the Curse of Dimensionality in Physics-Informed Machine Learning [0.0]
In the absence of labeled datasets, we utilize the PDE residual loss to learn the physical system, an approach known as physics-informed DeepONet. This method faces significant computational challenges, primarily due to the curse of dimensionality, as the computational cost increases exponentially with finer discretization. We introduce the Separable DeepONet framework to address these challenges and improve scalability for high-dimensional PDEs.
arXiv Detail & Related papers (2024-07-21T16:33:56Z)
Solving partial differential equations with sampled neural networks [1.8590821261905535]
Approximation of solutions to partial differential equations (PDE) is an important problem in computational science and engineering. We discuss how sampling the hidden weights and biases of the ansatz network from data-agnostic and data-dependent probability distributions allows us to progress on both challenges.
arXiv Detail & Related papers (2024-05-31T14:24:39Z)
Pretraining Codomain Attention Neural Operators for Solving Multiphysics PDEs [85.40198664108624]
We propose Codomain Attention Neural Operator (CoDA-NO) to solve multiphysics problems with PDEs. CoDA-NO tokenizes functions along the codomain or channel space, enabling self-supervised learning or pretraining of multiple PDE systems. We find CoDA-NO to outperform existing methods by over 36% on complex downstream tasks with limited data.
arXiv Detail & Related papers (2024-03-19T08:56:20Z)
Mixed formulation of physics-informed neural networks for thermo-mechanically coupled systems and heterogeneous domains [0.0]
Physics-informed neural networks (PINNs) are a new tool for solving boundary value problems. Recent investigations have shown that when designing loss functions for many engineering problems, using first-order derivatives and combining equations from both strong and weak forms can lead to much better accuracy. In this work, we propose applying the mixed formulation to solve multi-physical problems, specifically a stationary thermo-mechanically coupled system of equations.
arXiv Detail & Related papers (2023-02-09T21:56:59Z)
Solving High-Dimensional PDEs with Latent Spectral Models [74.1011309005488]
We present Latent Spectral Models (LSM) toward an efficient and precise solver for high-dimensional PDEs. Inspired by classical spectral methods in numerical analysis, we design a neural spectral block to solve PDEs in the latent space. LSM achieves consistent state-of-the-art and yields a relative gain of 11.5% averaged on seven benchmarks.
arXiv Detail & Related papers (2023-01-30T04:58:40Z)
Neural Basis Functions for Accelerating Solutions to High Mach Euler Equations [63.8376359764052]
We propose an approach to solving partial differential equations (PDEs) using a set of neural networks. We regress a set of neural networks onto a reduced order Proper Orthogonal Decomposition (POD) basis. These networks are then used in combination with a branch network that ingests the parameters of the prescribed PDE to compute a reduced order approximation to the PDE.
arXiv Detail & Related papers (2022-08-02T18:27:13Z)
Unsupervised Legendre-Galerkin Neural Network for Stiff Partial Differential Equations [9.659504024299896]
We propose an unsupervised machine learning algorithm based on the Legendre-Galerkin neural network to find an accurate approximation to the solution of different types of PDEs. The proposed neural network is applied to the general 1D and 2D PDEs as well as singularly perturbed PDEs that possess boundary layer behavior.
arXiv Detail & Related papers (2022-07-21T00:47:47Z)
Physics-constrained Unsupervised Learning of Partial Differential Equations using Meshes [1.066048003460524]
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.
arXiv Detail & Related papers (2022-03-30T19:22:56Z)
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)
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)
Neural Operator: Graph Kernel Network for Partial Differential Equations [57.90284928158383]
This work is to generalize neural networks so that they can learn mappings between infinite-dimensional spaces (operators) We formulate approximation of the infinite-dimensional mapping by composing nonlinear activation functions and a class of integral operators. Experiments confirm that the proposed graph kernel network does have the desired properties and show competitive performance compared to the state of the art solvers.
arXiv Detail & Related papers (2020-03-07T01:56:20Z)

This list is automatically generated from the titles and abstracts of the papers in this site.