English

Finite Sample Frequency Domain Identification

Systems and Control 2024-09-06 v2 Machine Learning Systems and Control Optimization and Control Machine Learning

Abstract

We study non-parametric frequency-domain system identification from a finite-sample perspective. We assume an open loop scenario where the excitation input is periodic and consider the Empirical Transfer Function Estimate (ETFE), where the goal is to estimate the frequency response at certain desired (evenly-spaced) frequencies, given input-output samples. We show that under sub-Gaussian colored noise (in time-domain) and stability assumptions, the ETFE estimates are concentrated around the true values. The error rate is of the order of O((du+dudy)M/Ntot)\mathcal{O}((d_{\mathrm{u}}+\sqrt{d_{\mathrm{u}}d_{\mathrm{y}}})\sqrt{M/N_{\mathrm{tot}}}), where NtotN_{\mathrm{tot}} is the total number of samples, MM is the number of desired frequencies, and du,dyd_{\mathrm{u}},\,d_{\mathrm{y}} are the dimensions of the input and output signals respectively. This rate remains valid for general irrational transfer functions and does not require a finite order state-space representation. By tuning MM, we obtain a Ntot1/3N_{\mathrm{tot}}^{-1/3} finite-sample rate for learning the frequency response over all frequencies in the H \mathcal{H}_{\infty} norm. Our result draws upon an extension of the Hanson-Wright inequality to semi-infinite matrices. We study the finite-sample behavior of ETFE in simulations.

Keywords

Cite

@article{arxiv.2404.01100,
  title  = {Finite Sample Frequency Domain Identification},
  author = {Anastasios Tsiamis and Mohamed Abdalmoaty and Roy S. Smith and John Lygeros},
  journal= {arXiv preprint arXiv:2404.01100},
  year   = {2024}
}

Comments

Version 2 changes: several typos were fixed and some proof steps were expanded

R2 v1 2026-06-28T15:40:14.521Z