Stable Linear Subspace Identification: A Machine Learning Approach
Abstract
Machine Learning (ML) and linear System Identification (SI) have been historically developed independently. In this paper, we leverage well-established ML tools - especially the automatic differentiation framework - to introduce SIMBa, a family of discrete linear multi-step-ahead state-space SI methods using backpropagation. SIMBa relies on a novel Linear-Matrix-Inequality-based free parametrization of Schur matrices to ensure the stability of the identified model. We show how SIMBa generally outperforms traditional linear state-space SI methods, and sometimes significantly, although at the price of a higher computational burden. This performance gap is particularly remarkable compared to other SI methods with stability guarantees, where the gain is frequently above 25% in our investigations, hinting at SIMBa's ability to simultaneously achieve state-of-the-art fitting performance and enforce stability. Interestingly, these observations hold for a wide variety of input-output systems and on both simulated and real-world data, showcasing the flexibility of the proposed approach. We postulate that this new SI paradigm presents a great extension potential to identify structured nonlinear models from data, and we hence open-source SIMBa on https://github.com/Cemempamoi/simba.
Keywords
Cite
@article{arxiv.2311.03197,
title = {Stable Linear Subspace Identification: A Machine Learning Approach},
author = {Loris Di Natale and Muhammad Zakwan and Bratislav Svetozarevic and Philipp Heer and Giancarlo Ferrari-Trecate and Colin N. Jones},
journal= {arXiv preprint arXiv:2311.03197},
year = {2024}
}
Comments
Accepted at ECC 2024