English

${L}^{\infty}$-norm computation for linear time-invariant systems depending on parameters

Symbolic Computation 2023-12-05 v2

Abstract

This paper focuses on representing the LL^{\infty}-norm of finite-dimensional linear time-invariant systems with parameter-dependent coefficients. Previous studies tackled the problem in a non-parametric scenario by simplifying it to finding the maximum yy-projection of real solutions (x,y)(x, y) of a system of the form Σ={P=0,P/x=0}\Sigma=\{P=0, \, \partial P/\partial x=0\}, where PZ[x,y]P \in \Z[x, y]. To solve this problem, standard computer algebra methods were employed and analyzed \cite{bouzidi2021computation}. In this paper, we extend our approach to address the parametric case. We aim to represent the "maximal" yy-projection of real solutions of Σ\Sigma as a function of the given parameters. %a set of parameters α\alpha. To accomplish this, we utilize cylindrical algebraic decomposition. This method allows us to determine the desired value as a function of the parameters within specific regions of parameter space.

Keywords

Cite

@article{arxiv.2312.00760,
  title  = {${L}^{\infty}$-norm computation for linear time-invariant systems depending on parameters},
  author = {Alban Quadrat and Fabrice Rouillier and Grace Younes},
  journal= {arXiv preprint arXiv:2312.00760},
  year   = {2023}
}
R2 v1 2026-06-28T13:38:38.558Z