Physics-informed neural networks for solving nonlinear diffusivity and Biot’s equations

Kadeethum, Teeratorn; Jørgensen, Thomas Martini; Nick, Hamidreza M.

doi:10.1371/journal.pone.0232683

Cited by 103 publications

(55 citation statements)

References 45 publications

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“…In the work done by Raissi et al [30,31,32], they named such strong form approach for differential equation as the physicsinformed neural network (PINN) for the first time. Today, the PINN becomes more and more popular in many engineering fields such as hydrogeology [7,18,35], geomechanics [19], cardiovascular system [21] and so on. One attractive feature of PINN is that it is fully differentiable with respect to all the input coordinates and free parameters, in other words, the trial solution (via the trained PINN) represents a smooth approximation that can be evaluated and differentiated continuously on the domain [9].…”

Section: Related Workmentioning

confidence: 99%

“…Solving these differential equations and obtaining parameter estimations from given observations are always intriguing topics, and significant research has been done to develop many advanced (semi-)analytical or numerical algorithms. While in the last decade, machine learning especially neural networks have yielded revolutionary results across diverse disciplines, including image and pattern recognition, natural language processing, genomics, and material constitutive modeling [15,23,26,34], among which a fair amount of research has also been done related to differential equations [1,9,12,13,17,18,19,22,24,25,27,28,29,30,31,32,33,35,36,38], owing to the dramatic increase in the computing resources. Therefore, it will be interesting to adopt neural networks as an important alternative to traditional mathematical methods to approximate the solutions to differential equations through iterative update of the network weights and biases.…”

Section: Introductionmentioning

confidence: 99%

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Data-Driven Solutions and Discoveries in Mechanics Using Physics Informed Neural Network

Zhang¹,

Chen²,

Yang³

2020

Preprint

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Deep learning has achieved remarkable success in diverse computer science applications, however, its use in other traditional engineering fields has emerged only recently. In this project, we solved several mechanics problems governed by differential equations, using physics informed neural networks (PINN). The PINN embeds the differential equations into the loss of the neural network using automatic differentiation. We present our developments in the context of solving two main classes of problems: data-driven solutions and data-driven discoveries, and we compare the results with either analytical solutions or numerical solutions using the finite element method. The remarkable achievements of the PINN model shown in this report suggest the bright prospect of the physics-informed surrogate models that are fully differentiable with respect to all input coordinates and free parameters. More broadly, this study shows that PINN provides an attractive alternative to solve traditional engineering problems.

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Section: Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Data-Driven Solutions and Discoveries in Mechanics Using Physics Informed Neural Network

Zhang¹,

Chen²,

Yang³

2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Meanwhile, physics-informed neural networks (PINNs) are neural networks trained to solve supervised learning tasks while satisfying the applicable laws of physics described by general nonlinear PDEs (Fang and Zhan, 2020). These PINNs can replace the traditional discretization methods with a neural network that approximates the solutions of differential equations (Raissi et al, 2019;Kadeethum et al, 2020). A PINN algorithm for solving brittle fracture problems by minimizing the variational energy of the system is presented by Goswami et al (2020), where the boundary conditions are entirely satisfied via appropriate modification of the neural network output.…”

Section: Introductionmentioning

confidence: 99%

Physics-informed neural networks for estimating stress transfer mechanics in single lap joints

Sharma

Awasthi

Sastry

et al. 2021

J. Zhejiang Univ. Sci. A

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With the explosive growth of computational resources and data generation, deep machine learning has been successfully employed in various applications. One important and emerging scientific application of deep learning involves solving differential equations. Here, physics-informed neural networks (PINNs) are developed to solve the differential equations associated with a specific scientific problem. As such, algorithms for solving the differential equations by embedding their initial and boundary conditions in the cost function of the artificial neural networks using algorithmic differentiation must also be developed. In this study, various PINNs are adopted to estimate the stresses in the tablets and the interphase of a single lap joint. The proposed model is represented by two fourth-order non-homogeneous coupled partial differential equations, with the axial stresses in the upper and lower tablets adopted as the dependent variables. The axial stresses are a function of the tablet length, which presents the independent variable. Therefore, the axial stresses in the tablets are estimated by solving the coupled partial differential equations when subjected to the boundary conditions, whereas the remaining stress components are expressed in terms of axial stresses. The results obtained using the developed methodology are validated using the results obtained via MAPLE software.

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“…This neural network model takes into account the physical laws contained in PDEs and encodes them into the neural network as regularization terms, which improves performance of the neural network model. Nowadays, physics-informed neural networks are gaining more and more attention from researchers and they are gradually being applied to various fields of research [32][33][34][35][36]. Jagtap et al [37] introduce adaptive activation functions into deep and physics-informed neural networks (PINNs) to better approximate complex functions and the solutions of partial differential equations.…”

Section: Introductionmentioning

confidence: 99%

Solving Partial Differential Equations Using Deep Learning and Physical Constraints

et al. 2020

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The various studies of partial differential equations (PDEs) are hot topics of mathematical research. Among them, solving PDEs is a very important and difficult task and, since many partial differential equations do not have analytical solutions, numerical methods are widely used to solve PDEs. Although numerical methods have been widely used with good performance, researchers are still searching for new methods for solving partial differential equations. In recent years, deep learning has achieved great success in many fields, such as image classification and natural language processing. Studies have shown that deep neural networks have powerful function-fitting capabilities and have great potential in the study of partial differential equations. In this paper, we introduce an improved Physics Informed Neural Network (PINN) for solving partial differential equations. PINN takes the physical information that is contained in partial differential equations as a regularization term, which improves the performance of neural networks. In this study, we use the method to study the wave equation, the KdV–Burgers equation, and the KdV equation. The experimental results show that PINN is effective in solving partial differential equations and deserves further research.

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Physics-informed neural networks for solving nonlinear diffusivity and Biot’s equations

Cited by 103 publications

References 45 publications

Data-Driven Solutions and Discoveries in Mechanics Using Physics Informed Neural Network

Data-Driven Solutions and Discoveries in Mechanics Using Physics Informed Neural Network

Physics-informed neural networks for estimating stress transfer mechanics in single lap joints

Solving Partial Differential Equations Using Deep Learning and Physical Constraints

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