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Generic bounds on the approximation error for physics-informed (and) operator learning
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Generic bounds on the approximation error for physics-informed (and) operator learning
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We propose a very general framework for deriving rigorous bounds on the approximation error for physics-informed neural networks (PINNs) and operator learning architectures such as DeepONets and FNOs as well as for physics-informed operator learning. These bounds guarantee that PINNs and (physics-informed) DeepONets or FNOs will efficiently approximate the underlying solution or solution operator of generic partial differential equations (PDEs). Our framework utilizes existing neural network approximation results to obtain bounds on more involved learning architectures for PDEs. We illustrate the general framework by deriving the first rigorous bounds on the approximation error of physics-informed operator learning and by showing that PINNs (and physics-informed DeepONets and FNOs) mitigate the curse of dimensionality in approximating nonlinear parabolic PDEs.
Forward citations
Cited by 2 Pith papers
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Reliable Error Estimation for PINNs: Lower and Upper A Posteriori Bounds
Derives computable two-sided a posteriori error bounds for PINN approximations of ODEs using localized strong monotonicity for lower bounds and one-sided Lipschitz for upper bounds.
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Physics-Informed Residuals for Adaptive Mesh Refinement in Finite-Difference PDE Solvers
PINN residuals serve as an off-grid probe to adaptively refine meshes before a finite-difference solve, yielding lower error with fewer degrees of freedom than uniform refinement on the 1D Burgers equation.
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