English

Approximation with Random Shallow ReLU Networks with Applications to Model Reference Adaptive Control

Optimization and Control 2024-04-18 v2 Machine Learning Systems and Control Systems and Control

Abstract

Neural networks are regularly employed in adaptive control of nonlinear systems and related methods of reinforcement learning. A common architecture uses a neural network with a single hidden layer (i.e. a shallow network), in which the weights and biases are fixed in advance and only the output layer is trained. While classical results show that there exist neural networks of this type that can approximate arbitrary continuous functions over bounded regions, they are non-constructive, and the networks used in practice have no approximation guarantees. Thus, the approximation properties required for control with neural networks are assumed, rather than proved. In this paper, we aim to fill this gap by showing that for sufficiently smooth functions, ReLU networks with randomly generated weights and biases achieve LL_{\infty} error of O(m1/2)O(m^{-1/2}) with high probability, where mm is the number of neurons. It suffices to generate the weights uniformly over a sphere and the biases uniformly over an interval. We show how the result can be used to get approximations of required accuracy in a model reference adaptive control application.

Keywords

Cite

@article{arxiv.2403.17142,
  title  = {Approximation with Random Shallow ReLU Networks with Applications to Model Reference Adaptive Control},
  author = {Andrew Lamperski and Tyler Lekang},
  journal= {arXiv preprint arXiv:2403.17142},
  year   = {2024}
}

Comments

Under Review for Conference on Decision and Control

R2 v1 2026-06-28T15:33:18.712Z