English

Stable-by-Design Neural Network-Based LPV State-Space Models for System Identification

Systems and Control 2025-10-30 v1 Artificial Intelligence Machine Learning Systems and Control

Abstract

Accurate modeling of nonlinear systems is essential for reliable control, yet conventional identification methods often struggle to capture latent dynamics while maintaining stability. We propose a \textit{stable-by-design LPV neural network-based state-space} (NN-SS) model that simultaneously learns latent states and internal scheduling variables directly from data. The state-transition matrix, generated by a neural network using the learned scheduling variables, is guaranteed to be stable through a Schur-based parameterization. The architecture combines an encoder for initial state estimation with a state-space representer network that constructs the full set of scheduling-dependent system matrices. For training the NN-SS, we develop a framework that integrates multi-step prediction losses with a state-consistency regularization term, ensuring robustness against drift and improving long-horizon prediction accuracy. The proposed NN-SS is evaluated on benchmark nonlinear systems, and the results demonstrate that the model consistently matches or surpasses classical subspace identification methods and recent gradient-based approaches. These findings highlight the potential of stability-constrained neural LPV identification as a scalable and reliable framework for modeling complex nonlinear systems.

Keywords

Cite

@article{arxiv.2510.24757,
  title  = {Stable-by-Design Neural Network-Based LPV State-Space Models for System Identification},
  author = {Ahmet Eren Sertbaş and Tufan Kumbasar},
  journal= {arXiv preprint arXiv:2510.24757},
  year   = {2025}
}

Comments

In the 12th International Conference of Image Processing, Wavelet and Applications on Real World Problems, 2025

R2 v1 2026-07-01T07:10:12.244Z