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Hauptverfasser: Sanchez, Ignacio, Fele, Filiberto, Limon, Daniel
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2511.14319
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author Sanchez, Ignacio
Fele, Filiberto
Limon, Daniel
author_facet Sanchez, Ignacio
Fele, Filiberto
Limon, Daniel
contents Robust data-driven controllers typically rely on datasets from previous experiments, which embed information on the variability of the system parameters across past operational conditions. Complementarily, data collected online can contribute to improving the feedback performance relative to the current system's conditions, but are unable to account for the overall -- possibly time-varying -- system operation. With this in mind, we consider the problem of stabilizing a time-varying linear system, whose parameters are only known to lie within a bounded polytopic set. Taking a robust data-driven approach, we synthesize the control law by simultaneously leveraging two sets of historical state and input measures: an offline dataset -- which covers the extreme variations of the system parameters -- and an online dataset consisting of a rolling window of the latest state and input samples. Our approach relies on the data informativity framework: we thus relax persistent excitation requirements (i.e., the collected samples need not be sufficient for system identification), while still allowing for the design of a stabilizing controller. The state feedback law is obtained from standard Lyapunov arguments, implemented via semi-definite optimization: this also yields an upper bound on the cost-to-go for the class of systems that are consistent with the online data, while guaranteeing a decreasing cost for all systems compatible with the offline data. Numerical experiments are presented to illustrate the effectiveness of the proposed controller.
format Preprint
id arxiv_https___arxiv_org_abs_2511_14319
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle An adaptive extension to robust data-driven predictive control under parametric uncertainty
Sanchez, Ignacio
Fele, Filiberto
Limon, Daniel
Systems and Control
Optimization and Control
93B45, 93B30
Robust data-driven controllers typically rely on datasets from previous experiments, which embed information on the variability of the system parameters across past operational conditions. Complementarily, data collected online can contribute to improving the feedback performance relative to the current system's conditions, but are unable to account for the overall -- possibly time-varying -- system operation. With this in mind, we consider the problem of stabilizing a time-varying linear system, whose parameters are only known to lie within a bounded polytopic set. Taking a robust data-driven approach, we synthesize the control law by simultaneously leveraging two sets of historical state and input measures: an offline dataset -- which covers the extreme variations of the system parameters -- and an online dataset consisting of a rolling window of the latest state and input samples. Our approach relies on the data informativity framework: we thus relax persistent excitation requirements (i.e., the collected samples need not be sufficient for system identification), while still allowing for the design of a stabilizing controller. The state feedback law is obtained from standard Lyapunov arguments, implemented via semi-definite optimization: this also yields an upper bound on the cost-to-go for the class of systems that are consistent with the online data, while guaranteeing a decreasing cost for all systems compatible with the offline data. Numerical experiments are presented to illustrate the effectiveness of the proposed controller.
title An adaptive extension to robust data-driven predictive control under parametric uncertainty
topic Systems and Control
Optimization and Control
93B45, 93B30
url https://arxiv.org/abs/2511.14319