Is the neural tangent kernel of PINNs deep learning general partial differential equations always convergent?
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Publication:6198233
DOI10.1016/j.physd.2023.133987MaRDI QIDQ6198233
Publication date: 21 February 2024
Published in: Physica D (Search for Journal in Brave)
partial differential equationsdeep learningconvergence conditionphysics-informed neural networksneural tangent kernel
Artificial neural networks and deep learning (68T07) Numerical methods for partial differential equations, initial value and time-dependent initial-boundary value problems (65M99) Numerical methods for partial differential equations, boundary value problems (65N99)
Cites Work
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- The Deep Ritz Method: a deep learning-based numerical algorithm for solving variational problems
- DGM: a deep learning algorithm for solving partial differential equations
- Data-driven peakon and periodic peakon solutions and parameter discovery of some nonlinear dispersive equations via deep learning
- Data-driven deep learning of partial differential equations in modal space
- A two-stage physics-informed neural network method based on conserved quantities and applications in localized wave solutions
- When and why PINNs fail to train: a neural tangent kernel perspective
- Data-driven rogue waves and parameters discovery in nearly integrable \(\mathcal{PT}\)-symmetric Gross-Pitaevskii equations via PINNs deep learning
- PDE-Net 2.0: learning PDEs from data with a numeric-symbolic hybrid deep network
- On the eigenvector bias of Fourier feature networks: from regression to solving multi-scale PDEs with physics-informed neural networks
- Physics-informed neural networks: a deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations
- A physics-informed variational DeepONet for predicting crack path in quasi-brittle materials
- Physics-informed neural network methods based on Miura transformations and discovery of new localized wave solutions
- Neural‐network‐based approximations for solving partial differential equations
- Solving parametric PDE problems with artificial neural networks
- On the Convergence of Physics Informed Neural Networks for Linear Second-Order Elliptic and Parabolic Type PDEs
- Learning data-driven discretizations for partial differential equations
- Approximation by superpositions of a sigmoidal function
- A deep learning method for solving third-order nonlinear evolution equations
- Complex dynamics on the one-dimensional quantum droplets via time piecewise PINNs
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