Neuro-PINN: a hybrid framework for efficient nonlinear projection equation solutions
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Publication:6569923
DOI10.1002/NME.7377MaRDI QIDQ6569923
Publication date: 9 July 2024
Published in: International Journal for Numerical Methods in Engineering (Search for Journal in Brave)
ordinary differential equationphysics-informed neural networknonlinear projection equationneurodynamic optimization
Mathematical programming (90Cxx) Artificial intelligence (68Txx) Parabolic equations and parabolic systems (35Kxx)
Cites Work
- Finite-dimensional variational inequality and nonlinear complementarity problems: A survey of theory, algorithms and applications
- A family of embedded Runge-Kutta formulae
- The Deep Ritz Method: a deep learning-based numerical algorithm for solving variational problems
- Variational inequality formulation for the games with random payoffs
- A mixed formulation for physics-informed neural networks as a potential solver for engineering problems in heterogeneous domains: comparison with finite element method
- Gradient-enhanced physics-informed neural networks for forward and inverse PDE problems
- Physics-informed neural networks for high-speed flows
- A collaborative neurodynamic approach to global and combinatorial optimization
- Conservative physics-informed neural networks on discrete domains for conservation laws: applications to forward and inverse problems
- Adaptive activation functions accelerate convergence in deep and physics-informed neural networks
- An energy approach to the solution of partial differential equations in computational mechanics via machine learning: concepts, implementation and applications
- Physics-informed neural networks: a deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations
- A new neural network for solving nonlinear projection equations
- Normal Maps Induced by Linear Transformations
- Solving high-dimensional partial differential equations using deep learning
- Estimates on the generalization error of physics-informed neural networks for approximating a class of inverse problems for PDEs
- DeepXDE: A Deep Learning Library for Solving Differential Equations
- Physics-Informed Neural Networks with Hard Constraints for Inverse Design
- Learning in Modal Space: Solving Time-Dependent Stochastic PDEs Using Physics-Informed Neural Networks
- A projection neural network and its application to constrained optimization problems
- Complementarity problems
- On the approximation of functions by tanh neural networks
- Enhanced physics‐informed neural networks for hyperelasticity
- Deep learning phase‐field model for brittle fractures
- A one-layer recurrent neural network for nonsmooth pseudoconvex optimization with quasiconvex inequality and affine equality constraints
- An Adaptive Continuous-Time Algorithm for Nonsmooth Convex Resource Allocation Optimization
- Meshless physics-informed deep learning method for three-dimensional solid mechanics
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