Identification of additive continuous-time systems in open and closed loop

Rodrigo A. González; K.H.J. Classens; Cristian R. Rojas; James S. Welsh; Tom A.E. Oomen

doi:10.1016/j.automatica.2024.112013

Identification of additive continuous-time systems in open and closed loop

Rodrigo A. González (Corresponding author), K.H.J. Classens, Cristian R. Rojas, James S. Welsh, Tom A.E. Oomen

Research output: Contribution to journal › Article › Academic › peer-review

3 Citations (Scopus)

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Abstract

When identifying electrical, mechanical, or biological systems, parametric continuous-time identification methods can lead to interpretable and parsimonious models when the model structure aligns with the physical properties of the system. Traditional linear system identification may not consider the most parsimonious model when relying solely on unfactored transfer functions, which typically result from standard direct approaches. This paper presents a novel identification method that delivers additive models for both open and closed-loop setups. The estimators that are derived are shown to be generically consistent, and can admit the identification of marginally stable additive systems. Numerical simulations show the efficacy of the proposed approach, and its performance in identifying a modal representation of a flexible beam is verified using experimental data.

Original language	English
Article number	112013
Number of pages	12
Journal	Automatica
Volume	173
DOIs	https://doi.org/10.1016/j.automatica.2024.112013
Publication status	Published - Mar 2025

Keywords

continuous-time system identification
parsimony
closed-loop system identification
refined instrumental variables

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10.1016/j.automatica.2024.112013

[Gonzalez2024] Additive identificationFinal author version , 2.3 MBLicence: CC BY-NC-ND
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Cite this

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AU - González, Rodrigo A.

AU - Classens, K.H.J.

AU - Rojas, Cristian R.

AU - Welsh, James S.

AU - Oomen, Tom A.E.

PY - 2025/3

Y1 - 2025/3

N2 - When identifying electrical, mechanical, or biological systems, parametric continuous-time identification methods can lead to interpretable and parsimonious models when the model structure aligns with the physical properties of the system. Traditional linear system identification may not consider the most parsimonious model when relying solely on unfactored transfer functions, which typically result from standard direct approaches. This paper presents a novel identification method that delivers additive models for both open and closed-loop setups. The estimators that are derived are shown to be generically consistent, and can admit the identification of marginally stable additive systems. Numerical simulations show the efficacy of the proposed approach, and its performance in identifying a modal representation of a flexible beam is verified using experimental data.

AB - When identifying electrical, mechanical, or biological systems, parametric continuous-time identification methods can lead to interpretable and parsimonious models when the model structure aligns with the physical properties of the system. Traditional linear system identification may not consider the most parsimonious model when relying solely on unfactored transfer functions, which typically result from standard direct approaches. This paper presents a novel identification method that delivers additive models for both open and closed-loop setups. The estimators that are derived are shown to be generically consistent, and can admit the identification of marginally stable additive systems. Numerical simulations show the efficacy of the proposed approach, and its performance in identifying a modal representation of a flexible beam is verified using experimental data.

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KW - parsimony

KW - closed-loop system identification

KW - refined instrumental variables

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Identification of additive continuous-time systems in open and closed loop

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