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This paper introduces DSGNAR, a second-order optimization framework that addresses the ill-conditioning of the loss landscape in physics-informed neural networks (PINNs), enabling them to achieve unprecedented accuracy and speed in solving partial differential equations. By coupling a doubly-sketched Gauss-Newton model with adaptive control of regularization and step length, DSGNAR significantly outperforms existing methods, achieving relative \( \ell_2 \) errors as low as \( 3 \times 10^{-16} \) and improving results on benchmark problems by up to eight orders of magnitude. The framework demonstrates robustness across various architectures and precision levels, making it a versatile tool for high-accuracy numerical solutions in complex physical systems.
Achieving relative \( \ell_2 \) errors as low as \( 3 \times 10^{-16} \) marks a transformative leap in the accuracy of physics-informed neural networks.
Physics-informed neural networks (PINNs) have emerged as a promising route to solve partial differential equations, yet they have struggled to reach the precision of classical solvers. The obstacle is increasingly understood to be one of optimisation, owing to the severely ill-conditioned loss landscape. We present $\textbf{DSGNAR}$: Doubly-Sketched Gauss-Newton with Adaptive Ratio, a scalable second-order optimisation framework that confronts this ill-conditioning and, in doing so, obtains unprecedented accuracy and speed. $\textbf{DSGNAR}$ couples a doubly-sketched Gauss-Newton model with a novel strategy that carefully controls both regularisation and step length. Across a suite of problems spanning nonlinear, chaotic, multi-scale, high-dimensional, and Navier-Stokes, the framework greatly improves on the state of the art: able to attain relative $\ell_2$ errors as low as $3\times10^{-16}$ in double precision, improve contemporary results by five orders of magnitude on the canonical Burgers'equation, and as much as eight orders on a high-dimensional Poisson problem, while remaining markedly faster. We further show that, in single precision, solutions at the limit of round-off error can be obtained very quickly: Burgers'equation to $\ell_2^{\text{rel}} = 4.75 \times 10^{-7}$ in under ten seconds. The framework is also robust to the choice of architecture, arithmetic precision, and initial hyperparameters. The code is available at https://www.github.com/wephy/physics-informed-neural-networks