Nystr\"om-Accelerated Primal LS-SVMs: Breaking the O(an3) Complexity Bottleneck for Scalable ODEs Learning

Abstract

A major problem of kernel-based methods (e.g., least squares support vector machines, LS-SVMs) for solving linear/nonlinear ordinary differential equations (ODEs) is the prohibitive O(an3) (a=1 for linear ODEs and 27 for nonlinear ODEs) part of their computational complexity with increasing temporal discretization points n. We propose a novel Nystr\"om-accelerated LS-SVMs framework that breaks this bottleneck by reformulating ODEs as primal-space constraints. Specifically, we derive for the first time an explicit Nystr\"om-based mapping and its derivatives from one-dimensional temporal discretization points to a higher m-dimensional feature space (1< m n), enabling the learning process to solve linear/nonlinear equation systems with m-dependent complexity. Numerical experiments on sixteen benchmark ODEs demonstrate: 1) 10-6000 times faster computation than classical LS-SVMs and physics-informed neural networks (PINNs), 2) comparable accuracy to LS-SVMs (<0.13\% relative MAE, RMSE, and \| y-y \| ∞ difference) while maximum surpassing PINNs by 72\% in RMSE, and 3) scalability to n=104 time steps with m=50 features. This work establishes a new paradigm for efficient kernel-based ODEs learning without significantly sacrificing the accuracy of the solution.

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