Solving multiscale steady radiative transfer equation using neural networks with uniform stability
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Publication:2157930
DOI10.1007/s40687-022-00345-zzbMath1492.65286arXiv2110.07037OpenAlexW3207183244MaRDI QIDQ2157930
Publication date: 22 July 2022
Published in: Research in the Mathematical Sciences (Search for Journal in Brave)
Full work available at URL: https://arxiv.org/abs/2110.07037
Artificial neural networks and deep learning (68T07) Numerical methods for integral equations (65R20) Integro-partial differential equations (45K05) Transport processes in time-dependent statistical mechanics (82C70) Numerical methods for partial differential equations, initial value and time-dependent initial-boundary value problems (65M99) Radiative heat transfer (80A21)
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Cites Work
- Unnamed Item
- Diffusion approximations and domain decomposition method of linear transport equations: asymptotics and numerics
- Numerical study of a domain decomposition method for a two-scale linear transport equation
- Boundary layers and homogenization of transport processes
- The Deep Ritz Method: a deep learning-based numerical algorithm for solving variational problems
- DGM: a deep learning algorithm for solving partial differential equations
- Trend to equilibrium for the kinetic Fokker-Planck equation via the neural network approach
- Solving the linear transport equation by a deep neural network approach
- When and why PINNs fail to train: a neural tangent kernel perspective
- An asymptotic-preserving IMEX method for nonlinear radiative transfer equation
- Stability-enhanced AP IMEX-LDG schemes for linear kinetic transport equations under a diffusive scaling
- A uniformly second order numerical method for the one-dimensional discrete-ordinate transport equation and its diffusion limit with interface
- Physics-informed neural networks: a deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations
- Asymptotic-Induced Domain Decomposition Methods for Kinetic and Drift Diffusion Semiconductor Equations
- An Asymptotic-Induced Scheme for Nonstationary Transport Equations in the Diffusive Limit
- Uniformly Accurate Diffusive Relaxation Schemes for Multiscale Transport Equations
- Numerical methods for kinetic equations
- Diffusion Approximation and Computation of the Critical Size
- Micro-Macro Schemes for Kinetic Equations Including Boundary Layers
- Implicit-Explicit Runge--Kutta Schemes for Hyperbolic Systems and Kinetic Equations in the Diffusion Limit
- A Boundary Functional for the Least-Squares Finite- Element Solution of Neutron Transport Problems
- Understanding and Mitigating Gradient Flow Pathologies in Physics-Informed Neural Networks
- Solving high-dimensional partial differential equations using deep learning
- Accurate Front Capturing Asymptotic Preserving Scheme for Nonlinear Gray Radiative Transfer Equation
- Algorithms for solving high dimensional PDEs: from nonlinear Monte Carlo to machine learning
- Estimates on the generalization error of physics-informed neural networks for approximating a class of inverse problems for PDEs
- An Implicit Unified Gas Kinetic Scheme for Radiative Transfer with Equilibrium and Non-Equilibrium Diffusive Limits
- Implicit Asymptotic Preserving Method for Linear Transport Equations
- The model reduction of the Vlasov–Poisson–Fokker–Planck system to the Poisson–Nernst–Planck system via the Deep Neural Network Approach
- A New Asymptotic Preserving Scheme Based on Micro-Macro Formulation for Linear Kinetic Equations in the Diffusion Limit
- Two Uniform Tailored Finite Point Schemes for the Two Dimensional Discrete Ordinates Transport Equations with Boundary and Interface Layers
- AnLptheory for stationary radiative transfer
- A Domain Decomposition Analysis for a Two-Scale Linear Transport Problem
- Understanding Machine Learning
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