Weak adversarial networks for high-dimensional partial differential equations

Zang, Yaohua; Bao, Gang; Ye, Xiaojing; Zhou, Haomin

doi:10.1016/j.jcp.2020.109409

Cited by 268 publications

(187 citation statements)

References 30 publications

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“…In the past decade, deep learning has achieved great success in many subjects, like computer vision, speech recognition, and natural language processing [7,11,18] due to the strong representability of deep neural networks (DNNs). Meanwhile, DNNs have also been used to solve partial differential equations (PDEs); see for example [1,4,5,8,19,22,24,26,28]. In classical numerical methods such as finite difference method [20] and finite element method [2], the number of degrees of freedoms (dofs) grows exponentially fast as the dimension of PDE increases.…”

Section: Introductionmentioning

confidence: 99%

“…Afterwards, Monte-Carlo method is used to approximate the loss (objective) function which is defined over a high-dimensional space. Some methods are based on the PDE itself [24,26] and some other methods are based on the variational or the weak formulation [5,16,21,28]. Another successful example is the multilevel Picard approximation which is provable to overcome the curse of dimensionality for a class of semilinear parabolic equations [13].…”

Section: Introductionmentioning

confidence: 99%

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A Comparison Study of Deep Galerkin Method and Deep Ritz Method for Elliptic Problems with Different Boundary Conditions

Chen¹

2020

CMR

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Recent years have witnessed growing interests in solving partial differential equations by deep neural networks, especially in the high-dimensional case. Unlike classical numerical methods, such as finite difference method and finite element method, the enforcement of boundary conditions in deep neural networks is highly nontrivial. One general strategy is to use the penalty method. In the work, we conduct a comparison study for elliptic problems with four different boundary conditions, i.e., Dirichlet, Neumann, Robin, and periodic boundary conditions, using two representative methods: deep Galerkin method and deep Ritz method. In the former, the PDE residual is minimized in the least-squares sense while the corresponding variational problem is minimized in the latter. Therefore, it is reasonably expected that deep Galerkin method works better for smooth solutions while deep Ritz method works better for low-regularity solutions. However, by a number of examples, we observe that deep Ritz method can outperform deep Galerkin method with a clear dependence of dimensionality even for smooth solutions and deep Galerkin method can also outperform deep Ritz method for low-regularity solutions. Besides, in some cases, when the boundary condition can be implemented in an exact manner, we find that such a strategy not only provides a better approximate solution but also facilitates the training process.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Comparison Study of Deep Galerkin Method and Deep Ritz Method for Elliptic Problems with Different Boundary Conditions

Chen¹

2020

CMR

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“…In recent years, neural networks have shown great success in representing highdimensional classifiers or probability distributions in a variety of machine learning tasks and have led to the tremendous success and popularity of deep learning [32,38]. Motivated by those recent success, researchers have been actively exploring using deep learning techniques to solve high dimensional PDEs [10,18,22,23,29,37,45,48] by using neural networks to parameterize the unknown solution of high dimensional PDEs. Thanks to the flexibility of the neural network approximations, such methods have achieved remarkable results for various kind of PDE problems, including eigenvalue problems for many-body quantum systems (see e.g., [7,9,12,19,[24][25][26]36]), where the high dimensional wave functions are parameterized by neural networks with specific architecture design to address the symmetry properties of many-body quantum systems.…”

Section: Introductionmentioning

confidence: 99%

A priori generalization error analysis of two-layer neural networks for solving high dimensional Schrödinger eigenvalue problems

2022

Comm. Amer. Math. Soc.

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This paper analyzes the generalization error of two-layer neural networks for computing the ground state of the Schrödinger operator on a d d -dimensional hypercube with Neumann boundary condition. We prove that the convergence rate of the generalization error is independent of dimension d d , under the a priori assumption that the ground state lies in a spectral Barron space. We verify such assumption by proving a new regularity estimate for the ground state in the spectral Barron space. The latter is achieved by a fixed point argument based on the Krein-Rutman theorem.

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“…[21,30] provides multi-scale deep neural network methods which separate different frequencies of the loss function and approximate them by the corresponding neural networks. [37] considers variational problems, and the loss function is defined as a weak formulation. To deal with the essential boundary conditions, [20] resorts to Nitsche's variational formulation.…”

Section: Introductionmentioning

confidence: 99%

“…Addressing the issue of deep learning methods, [29] proposes a Monte Carlo method to approximate second order derivatives. In [32,37], the variational form reduces the order of derivatives through the integration by parts. [11] proposes a derivative free method for parabolic PDEs by solving the equivalent BSDE problem.…”

Section: Introductionmentioning

confidence: 99%

A Local Deep Learning Method for Solving High Order Partial Differential Equations

Zhu¹,

Yang²

2022

NMTMA

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At present, deep learning based methods are being employed to resolve the computational challenges of high-dimensional partial differential equations (PDEs). But the computation of the high order derivatives of neural networks is costly, and high order derivatives lack robustness for training purposes. We propose a novel approach to solving PDEs with high order derivatives by simultaneously approximating the function value and derivatives. We introduce intermediate variables to rewrite the PDEs into a system of low order differential equations as what is done in the local discontinuous Galerkin method. The intermediate variables and the solutions to the PDEs are simultaneously approximated by a multi-output deep neural network. By taking the residual of the system as a loss function, we can optimize the network parameters to approximate the solution. The whole process relies on low order derivatives. Numerous numerical examples are carried out to demonstrate that our local deep learning is efficient, robust, flexible, and is particularly well-suited for high-dimensional PDEs with high order derivatives.

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Weak adversarial networks for high-dimensional partial differential equations

Cited by 268 publications

References 30 publications

A Comparison Study of Deep Galerkin Method and Deep Ritz Method for Elliptic Problems with Different Boundary Conditions

A Comparison Study of Deep Galerkin Method and Deep Ritz Method for Elliptic Problems with Different Boundary Conditions

A priori generalization error analysis of two-layer neural networks for solving high dimensional Schrödinger eigenvalue problems

A Local Deep Learning Method for Solving High Order Partial Differential Equations

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