English

KO: Kinetics-inspired Neural Optimizer with PDE Simulation Approaches

Machine Learning 2025-05-22 v1 Artificial Intelligence

Abstract

The design of optimization algorithms for neural networks remains a critical challenge, with most existing methods relying on heuristic adaptations of gradient-based approaches. This paper introduces KO (Kinetics-inspired Optimizer), a novel neural optimizer inspired by kinetic theory and partial differential equation (PDE) simulations. We reimagine the training dynamics of network parameters as the evolution of a particle system governed by kinetic principles, where parameter updates are simulated via a numerical scheme for the Boltzmann transport equation (BTE) that models stochastic particle collisions. This physics-driven approach inherently promotes parameter diversity during optimization, mitigating the phenomenon of parameter condensation, i.e. collapse of network parameters into low-dimensional subspaces, through mechanisms analogous to thermal diffusion in physical systems. We analyze this property, establishing both a mathematical proof and a physical interpretation. Extensive experiments on image classification (CIFAR-10/100, ImageNet) and text classification (IMDB, Snips) tasks demonstrate that KO consistently outperforms baseline optimizers (e.g., Adam, SGD), achieving accuracy improvements while computation cost remains comparable.

Keywords

Cite

@article{arxiv.2505.14777,
  title  = {KO: Kinetics-inspired Neural Optimizer with PDE Simulation Approaches},
  author = {Mingquan Feng and Yixin Huang and Yifan Fu and Shaobo Wang and Junchi Yan},
  journal= {arXiv preprint arXiv:2505.14777},
  year   = {2025}
}
R2 v1 2026-07-01T02:26:24.591Z