☆ 4.7 Article

Physics-informed graph neural Galerkin networks: A unified framework for solving PDE-governed forward and inverse problems

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2022)

Related references

Note: Only part of the references are listed.

Article Computer Science, Artificial Intelligence

Graph Neural Networks With Convolutional ARMA Filters

Filippo Maria Bianchi et al.

Summary: This paper proposes a novel graph convolutional layer based on the auto-regressive moving average (ARMA) filter, which provides a more flexible frequency response, is more robust to noise, and better captures the global graph structure compared to polynomial filters. Experimental results show significant improvements of the proposed ARMA layer over graph neural networks based on polynomial filters.

IEEE TRANSACTIONS ON PATTERN ANALYSIS AND MACHINE INTELLIGENCE (2022)

Add to Collection

Article Engineering, Multidisciplinary

hp-VPINNs: Variational physics-informed neural networks with domain decomposition

Ehsan Kharazmi et al.

Summary: The study proposes a general framework for hp-variational physics-informed neural networks (hp-VPINNs) based on the nonlinear approximation of shallow and deep neural networks and hp-refinement via domain decomposition and projection onto high-order polynomials. The hp-refinement corresponds to a global approximation with a local learning algorithm for efficient network parameter optimization, demonstrating advantages in accuracy and training cost for function approximation and solving differential equations.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2021)

Add to Collection

Article Computer Science, Interdisciplinary Applications

NSFnets (Navier-Stokes flow nets): Physics-informed neural networks for the incompressible Navier-Stokes equations

Xiaowei Jin et al.

Summary: In the past 50 years, significant progress has been made in solving Navier-Stokes equations using various numerical methods, but challenges still exist in incorporating multi-fidelity data seamlessly and mesh generation for complex industrial applications. Physics-informed neural networks (PINNs) are employed to directly encode governing equations into deep neural networks, overcoming some limitations for simulating incompressible laminar and turbulent flows. The Navier-Stokes flow nets (NSFnets) are developed using velocity-pressure (VP) and vorticity-velocity (VV) formulations, showing promise in accuracy and convergence rate for benchmark problems as well as turbulent channel flows.

JOURNAL OF COMPUTATIONAL PHYSICS (2021)

Add to Collection

Article Engineering, Multidisciplinary

DiscretizationNet: A machine-learning based solver for Navier-Stokes equations using finite volume discretization

Rishikesh Ranade et al.

Summary: This work aims to develop an ML-based PDE solver that combines important characteristics of existing PDE solvers with ML technologies. By using discretization and iterative algorithms, the ML-solver can achieve good accuracy, stability, and faster convergence in solving highly non-linear, coupled PDE solutions.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2021)

Add to Collection

Article Mechanics

Teaching the incompressible Navier-Stokes equations to fast neural surrogate models in three dimensions

Nils Wandel et al.

Summary: This work introduces significant extensions to a deep learning framework for fluid simulations, enabling fast and accurate 3D simulations while conditioning the neural fluid model on additional information about viscosity and density. The method allows for simulating laminar and turbulent flows without prior fluid simulation data, showing improvements in accuracy, speed, and generalization capabilities compared to current 3D NN-based fluid models.

PHYSICS OF FLUIDS (2021)

Add to Collection

Article Multidisciplinary Sciences

Artificial intelligence velocimetry and microaneurysm-on-a-chip for three-dimensional analysis of blood flow in physiology and disease

Shengze Cai et al.

Summary: Understanding blood flow mechanics is crucial for understanding physiological mechanisms and vascular diseases in microcirculation. Conventional methods lack the ability to accurately assess flow fields, while artificial-intelligence velocimetry (AIV) provides a new approach by integrating imaging data with underlying physics to quantify blood flow velocity and stress fields for assessing vascular injury.

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA (2021)

Add to Collection

Article Mechanics

Uncovering near-wall blood flow from sparse data with physics-informed neural networks

Amirhossein Arzani et al.

Summary: Physics-informed neural networks (PINNs) show high accuracy in hemodynamics modeling; even with very few measurement points, accurate quantification of blood flow characteristics can be achieved without clear boundary conditions; the proposed hybrid data-driven and physics-based deep learning framework has the potential to achieve high-fidelity near-wall hemodynamics modeling in cardiovascular disease.

PHYSICS OF FLUIDS (2021)

Add to Collection

Article Mechanics

Super-resolution and denoising of fluid flow using physics-informed convolutional neural networks without high-resolution labels

Han Gao et al.

Summary: This study introduces a physics-informed deep learning super-resolution solution using convolutional neural networks, which can generate high-resolution flow fields from low-resolution inputs in high-dimensional parameter space without the need for high-resolution labels. The method can be applied for super-resolution, denoising, and parametric inference purposes.

PHYSICS OF FLUIDS (2021)

Add to Collection

Article Mathematics, Applied

DeepXDE: A Deep Learning Library for Solving Differential Equations

Lu Lu et al.

Summary: This article introduces an overview, implementation and applications of Physics-Informed Neural Networks (PINNs), along with a new residual-based adaptive refinement (RAR) method. By comparing with finite element methods, the advantages of PINNs and the versatile applications of the Python library DeepXDE are demonstrated. Overall, DeepXDE contributes to the more rapid development of the emerging scientific machine learning field.

SIAM REVIEW (2021)

Add to Collection

Article Engineering, Multidisciplinary

Surrogate modeling for fluid flows based on physics-constrained deep learning without simulation data

Luning Sun et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Computer Science, Interdisciplinary Applications

Modeling the dynamics of PDE systems with physics-constrained deep auto-regressive networks

Nicholas Geneva et al.

JOURNAL OF COMPUTATIONAL PHYSICS (2020)

Add to Collection

Article Engineering, Multidisciplinary

Machine learning in cardiovascular flows modeling: Predicting arterial blood pressure from non-invasive 4D flow MRI data using physics-informed neural networks

Georgios Kissas et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Engineering, Multidisciplinary

Physics-informed neural networks for high-speed flows

Zhiping Mao et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Multidisciplinary Sciences

Hidden fluid mechanics: Learning velocity and pressure fields from flow visualizations

Maziar Raissi et al.

SCIENCE (2020)

Add to Collection

Article Physics, Multidisciplinary

Physics-Informed Neural Networks for Cardiac Activation Mapping

Francisco Sahli Costabal et al.

FRONTIERS IN PHYSICS (2020)

Add to Collection

Article Engineering, Multidisciplinary

FEA-Net: A physics-guided data-driven model for efficient mechanical response prediction

Houpu Yao et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Engineering, Multidisciplinary

An energy approach to the solution of partial differential equations in computational mechanics via machine learning: Concepts, implementation and applications

E. Samaniego et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Optics

Physics-informed neural networks for inverse problems in nano-optics and metamaterials

Yuyao Chen et al.

OPTICS EXPRESS (2020)

Add to Collection

Article Engineering, Multidisciplinary

Conservative physics-informed neural networks on discrete domains for conservation laws: Applications to forward and inverse problems

Ameya D. Jagtap et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Engineering, Civil

Physics-guided convolutional neural network (PhyCNN) for data-driven seismic response modeling

Ruiyang Zhang et al.

ENGINEERING STRUCTURES (2020)

Add to Collection

Article Computer Science, Interdisciplinary Applications

Weak adversarial networks for high-dimensional partial differential equations

Yaohua Zang et al.

JOURNAL OF COMPUTATIONAL PHYSICS (2020)

Add to Collection

Article Engineering, Multidisciplinary

Physics-informed multi-LSTM networks for metamodeling of nonlinear structures

Ruiyang Zhang et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Engineering, Multidisciplinary

Multi-level convolutional autoencoder networks for parametric prediction of spatio-temporal dynamics

Jiayang Xu et al.

COMPUTER METHODS IN APPLIED MECHANICS AND ENGINEERING (2020)

Add to Collection

Article Mechanics

Physics-constrained bayesian neural network for fluid flow reconstruction with sparse and noisy data

Luning Sun et al.

THEORETICAL AND APPLIED MECHANICS LETTERS (2020)

Add to Collection

Article Computer Science, Interdisciplinary Applications

Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations

M. Raissi et al.

JOURNAL OF COMPUTATIONAL PHYSICS (2019)

Add to Collection

Article Computer Science, Interdisciplinary Applications

Physics-constrained deep learning for high-dimensional surrogate modeling and uncertainty quantification without labeled data

Yinhao Zhu et al.

JOURNAL OF COMPUTATIONAL PHYSICS (2019)

Add to Collection

Article Mathematics, Interdisciplinary Applications

Prediction of aerodynamic flow fields using convolutional neural networks

Saakaar Bhatnagar et al.

COMPUTATIONAL MECHANICS (2019)

Add to Collection

Article Computer Science, Artificial Intelligence

A unified deep artificial neural network approach to partial differential equations in complex geometries

Jens Berg et al.

NEUROCOMPUTING (2018)

Add to Collection

Article Mathematics

The Deep Ritz Method: A Deep Learning-Based Numerical Algorithm for Solving Variational Problems

E. Weinan et al.

COMMUNICATIONS IN MATHEMATICS AND STATISTICS (2018)

Add to Collection

© Peeref 2019-2024. All rights reserved.