Machine Learning and Computational Mathematics
From MaRDI portal
Publication:5162355
DOI10.4208/cicp.OA-2020-0185zbMath1473.00035arXiv2009.14596OpenAlexW3105606612MaRDI QIDQ5162355
Publication date: 2 November 2021
Published in: Communications in Computational Physics (Search for Journal in Brave)
Full work available at URL: https://arxiv.org/abs/2009.14596
Learning and adaptive systems in artificial intelligence (68T05) General applied mathematics (00A69) General theory of mathematical modeling (00A71)
Related Items (18)
Generalization Error Analysis of Neural Networks with Gradient Based Regularization ⋮ High Order Deep Neural Network for Solving High Frequency Partial 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 ⋮ A Deep Learning Method for Elliptic Hemivariational Inequalities ⋮ Neural control of discrete weak formulations: Galerkin, least squares \& minimal-residual methods with quasi-optimal weights ⋮ MOD-Net: A Machine Learning Approach via Model-Operator-Data Network for Solving PDEs ⋮ A Chebyshev Polynomial Neural Network Solver for Boundary Value Problems of Elliptic Equations ⋮ A Hybrid Method for Three-Dimensional Semi-Linear Elliptic Equations ⋮ DPK: Deep Neural Network Approximation of the First Piola-Kirchhoff Stress ⋮ Convergence Analysis of a Quasi-Monte CarloBased Deep Learning Algorithm for Solving Partial Differential Equations ⋮ Improved Analysis of PINNs: Alleviate the CoD for Compositional Solutions ⋮ DNN-HDG: a deep learning hybridized discontinuous Galerkin method for solving some elliptic problems ⋮ Subspace decomposition based DNN algorithm for elliptic type multi-scale PDEs ⋮ Port-metriplectic neural networks: thermodynamics-informed machine learning of complex physical systems ⋮ Failure-Informed Adaptive Sampling for PINNs ⋮ Monte Carlo fPINNs: deep learning method for forward and inverse problems involving high dimensional fractional partial differential equations ⋮ A Local Deep Learning Method for Solving High Order Partial Differential Equations
Cites Work
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Deep learning-based numerical methods for high-dimensional parabolic partial differential equations and backward stochastic differential equations
- The heterogeneous multiscale methods
- Machine learning from a continuous viewpoint. I
- A priori estimates of the population risk for two-layer neural networks
- Mean field analysis of neural networks: a central limit theorem
- The heterogeneous multiscale method
- Universal approximation bounds for superpositions of a sigmoidal function
- A mean field view of the landscape of two-layer neural networks
- Solving high-dimensional partial differential equations using deep learning
- Deep Potential: A General Representation of a Many-Body Potential Energy Surface
- Uniformly accurate machine learning-based hydrodynamic models for kinetic equations
- Breaking the Curse of Dimensionality with Convex Neural Networks
This page was built for publication: Machine Learning and Computational Mathematics
