English

FxTS-Net: Fixed-Time Stable Learning Framework for Neural ODEs

Optimization and Control 2024-11-15 v1 Machine Learning

Abstract

Neural Ordinary Differential Equations (Neural ODEs), as a novel category of modeling big data methods, cleverly link traditional neural networks and dynamical systems. However, it is challenging to ensure the dynamics system reaches a correctly predicted state within a user-defined fixed time. To address this problem, we propose a new method for training Neural ODEs using fixed-time stability (FxTS) Lyapunov conditions. Our framework, called FxTS-Net, is based on the novel FxTS loss (FxTS-Loss) designed on Lyapunov functions, which aims to encourage convergence to accurate predictions in a user-defined fixed time. We also provide an innovative approach for constructing Lyapunov functions to meet various tasks and network architecture requirements, achieved by leveraging supervised information during training. By developing a more precise time upper bound estimation for bounded non-vanishingly perturbed systems, we demonstrate that minimizing FxTS-Loss not only guarantees FxTS behavior of the dynamics but also input perturbation robustness. For optimising FxTS-Loss, we also propose a learning algorithm, in which the simulated perturbation sampling method can capture sample points in critical regions to approximate FxTS-Loss. Experimentally, we find that FxTS-Net provides better prediction performance and better robustness under input perturbation.

Keywords

Cite

@article{arxiv.2411.09118,
  title  = {FxTS-Net: Fixed-Time Stable Learning Framework for Neural ODEs},
  author = {Chaoyang Luo and Yan Zou and Wanying Li and Nanjing Huang},
  journal= {arXiv preprint arXiv:2411.09118},
  year   = {2024}
}
R2 v1 2026-06-28T19:59:20.446Z