Neural‐network‐based approximations for solving partial differential equations

Gradient-enhanced physics-informed neural networks based on transfer learning for inverse problems of the variable coefficient differential equations, Neural Control of Parametric Solutions for High-Dimensional Evolution PDEs, wPINNs: Weak Physics Informed Neural Networks for Approximating Entropy Solutions of Hyperbolic Conservation Laws, Is the neural tangent kernel of PINNs deep learning general partial differential equations always convergent?, Physics-informed ConvNet: learning physical field from a shallow neural network, Adaptive two-layer ReLU neural network. I: Best least-squares approximation, Solving forward and inverse problems of the logarithmic nonlinear Schrödinger equation with \(\mathcal{PT}\)-symmetric harmonic potential via deep learning, On some neural network architectures that can represent viscosity solutions of certain high dimensional Hamilton-Jacobi partial differential equations, Structure probing neural network deflation, Deep least-squares methods: an unsupervised learning-based numerical method for solving elliptic PDEs, Int-Deep: a deep learning initialized iterative method for nonlinear problems, Stationary Density Estimation of Itô Diffusions Using Deep Learning, On a multilevel Levenberg–Marquardt method for the training of artificial neural networks and its application to the solution of partial differential equations, SelectNet: self-paced learning for high-dimensional partial differential equations, Physics-informed neural networks for solving forward and inverse flow problems via the Boltzmann-BGK formulation, A fast and accurate physics-informed neural network reduced order model with shallow masked autoencoder, Gradient-enhanced physics-informed neural networks for forward and inverse PDE problems, Neural networks enforcing physical symmetries in nonlinear dynamical lattices: the case example of the Ablowitz-Ladik model, A mesh-free method using piecewise deep neural network for elliptic interface problems, CAN-PINN: a fast physics-informed neural network based on coupled-automatic-numerical differentiation method, Polynomial neural forms using feedforward neural networks for solving differential equations, VPVnet: A Velocity-Pressure-Vorticity Neural Network Method for the Stokes’ Equations under Reduced Regularity, An Augmented Lagrangian Deep Learning Method for Variational Problems with Essential Boundary Conditions, Deep neural network approximations for solutions of PDEs based on Monte Carlo algorithms, Scientific machine learning through physics-informed neural networks: where we are and what's next, Numerical solution for high order differential equations using a hybrid neural network-optimization method, Physics Informed Neural Networks (PINNs) For Approximating Nonlinear Dispersive PDEs, Solving flows of dynamical systems by deep neural networks and a novel deep learning algorithm, Imaging conductivity from current density magnitude using neural networks*, HomPINNs: Homotopy physics-informed neural networks for learning multiple solutions of nonlinear elliptic differential equations, Designing phononic crystal with anticipated band gap through a deep learning based data-driven method, On computing the hyperparameter of extreme learning machines: algorithm and application to computational PDEs, and comparison with classical and high-order finite elements, Physics and equality constrained artificial neural networks: application to forward and inverse problems with multi-fidelity data fusion, ModalPINN: an extension of physics-informed neural networks with enforced truncated Fourier decomposition for periodic flow reconstruction using a limited number of imperfect sensors, Wavelet neural networks functional approximation and application, Solving 2D and 3D Poisson equations and biharmonic equations by the Haar wavelet method, Buckling analysis of a beam-column using multilayer perceptron neural network technique, A discontinuity capturing shallow neural network for elliptic interface problems, Deep learning neural networks for the third-order nonlinear Schrödinger equation: bright solitons, breathers, and rogue waves, Application of the dynamical system method and the deep learning method to solve the new (3+1)-dimensional fractional modified Benjamin-Bona-Mahony equation, Physics-Informed Neural Networks for Solving Dynamic Two-Phase Interface Problems, VC-PINN: variable coefficient physics-informed neural network for forward and inverse problems of PDEs with variable coefficient, PI-VAE: physics-informed variational auto-encoder for stochastic differential equations, The deep minimizing movement scheme, Solving non-linear Kolmogorov equations in large dimensions by using deep learning: a numerical comparison of discretization schemes, MOD-Net: A Machine Learning Approach via Model-Operator-Data Network for Solving PDEs, A dimension-augmented physics-informed neural network (DaPINN) with high level accuracy and efficiency, FluxNet: a physics-informed learning-based Riemann solver for transcritical flows with non-ideal thermodynamics, DAS-PINNs: a deep adaptive sampling method for solving high-dimensional partial differential equations, Data-driven vortex solitons and parameter discovery of 2D generalized nonlinear Schrödinger equations with a \(\mathcal{PT}\)-symmetric optical lattice, Learning high frequency data via the coupled frequency predictor-corrector triangular DNN, Friedrichs Learning: Weak Solutions of Partial Differential Equations via Deep Learning, Error estimates and physics informed augmentation of neural networks for thermally coupled incompressible Navier Stokes equations, Investigating and Mitigating Failure Modes in Physics-Informed Neural Networks (PINNs), Higher-order error estimates for physics-informed neural networks approximating the primitive equations, Neural Galerkin schemes with active learning for high-dimensional evolution equations, HomPINNs: homotopy physics-informed neural networks for solving the inverse problems of nonlinear differential equations with multiple solutions, An extreme learning machine-based method for computational PDEs in higher dimensions, Neural network architectures using min-plus algebra for solving certain high-dimensional optimal control problems and Hamilton-Jacobi PDEs, Transferable neural networks for partial differential equations, Physics-informed neural network methods based on Miura transformations and discovery of new localized wave solutions, Loss-attentional physics-informed neural networks, A conservative hybrid deep learning method for Maxwell-Ampère-Nernst-Planck equations, Optimal control by deep learning techniques and its applications on epidemic models, Error analysis of deep Ritz methods for elliptic equations, Boundary-safe PINNs extension: application to non-linear parabolic PDEs in counterparty credit risk, Stochastic projection based approach for gradient free physics informed learning, A symmetry group based supervised learning method for solving partial differential equations, Solving groundwater flow equation using physics-informed neural networks, An artificial neural network approach to identify the parameter in a nonlinear subdiffusion model, Learning the random variables in Monte Carlo simulations with stochastic gradient descent: Machine learning for parametric PDEs and financial derivative pricing, On the spectral bias of coupled frequency predictor-corrector triangular DNN: the convergence analysis, A nonlinear-manifold reduced-order model and operator learning for partial differential equations with sharp solution gradients, An overview on deep learning-based approximation methods for partial differential equations, Greedy training algorithms for neural networks and applications to PDEs, BI-GreenNet: learning Green's functions by boundary integral network, Solving initial-boundary value problems for systems of partial differential equations using neural networks and optimization techniques, ConvPDE-UQ: convolutional neural networks with quantified uncertainty for heterogeneous elliptic partial differential equations on varied domains, DeepXDE: A Deep Learning Library for Solving Differential Equations, DNN-state identification of 2D distributed parameter systems, Artificial neural network approximations of Cauchy inverse problem for linear PDEs, On the Convergence of Physics Informed Neural Networks for Linear Second-Order Elliptic and Parabolic Type PDEs, A meshless method using the Takagi-Sugeno fuzzy model, Establishing criteria to ensure successful feedforward artificial neural network modelling of mechanical systems, Analytical solutions of boundary values problem of 2D and 3D Poisson and biharmonic equations by homotopy decomposition method, PPINN: parareal physics-informed neural network for time-dependent PDEs, Numerical methods for solving fuzzy equations: a survey, Unnamed Item, fPINNs: Fractional Physics-Informed Neural Networks, 3D nonparametric neural identification, Data-driven peakon and periodic peakon solutions and parameter discovery of some nonlinear dispersive equations via deep learning, Weak adversarial networks for high-dimensional partial differential equations, Data-driven discoveries of Bäcklund transformations and soliton evolution equations via deep neural network learning schemes, Overcoming the curse of dimensionality for some Hamilton-Jacobi partial differential equations via neural network architectures, Galerkin Neural Networks: A Framework for Approximating Variational Equations with Error Control, The distortion of the Peregrine soliton under the perturbation in initial condition, Error analysis for physics-informed neural networks (PINNs) approximating Kolmogorov PDEs, Efficient coupled deep neural networks for the time-dependent coupled Stokes-Darcy problems, Solving partial differential equation based on extreme learning machine, Optimal control of PDEs using physics-informed neural networks, Mesh-free radial basis function network methods with domain decomposition for approximation of functions and numerical solution of Poisson's equations, Uniform convergence guarantees for the deep Ritz method for nonlinear problems, Self-adaptive physics-informed neural networks, Two neural-network-based methods for solving elliptic obstacle problems

• Multilayer feedforward networks are universal approximators