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Autores principales: Gootzen, Julian, Chong, Michelle S.
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2604.23217
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author Gootzen, Julian
Chong, Michelle S.
author_facet Gootzen, Julian
Chong, Michelle S.
contents Motivated by the need for real-time health monitoring of power distribution grids, we propose a secure state estimator design for continuous time Lur'e type systems with non-uniformly and synchronously sampled outputs which have potentially been maliciously corrupted. The secure state estimator provides state estimates with accuracy independent of the sensor attack, when less than half of the sensors are under attack and when all inter-sample times are upper bounded. We show convergence of the state estimation error under an impulsive system framework and provide an upper bound on the estimation error that is independent of the attack signals. The stability conditions are formulated as linear matrix inequalities, which can be used to design the observer parameters. We demonstrate the capabilities of the proposed secure state estimator on a low-voltage power distribution grid.
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publishDate 2026
record_format arxiv
spellingShingle Secure estimator design for Lur'e-type systems with nonuniformly and synchronously sampled measurements under attacks [extended version]
Gootzen, Julian
Chong, Michelle S.
Optimization and Control
Motivated by the need for real-time health monitoring of power distribution grids, we propose a secure state estimator design for continuous time Lur'e type systems with non-uniformly and synchronously sampled outputs which have potentially been maliciously corrupted. The secure state estimator provides state estimates with accuracy independent of the sensor attack, when less than half of the sensors are under attack and when all inter-sample times are upper bounded. We show convergence of the state estimation error under an impulsive system framework and provide an upper bound on the estimation error that is independent of the attack signals. The stability conditions are formulated as linear matrix inequalities, which can be used to design the observer parameters. We demonstrate the capabilities of the proposed secure state estimator on a low-voltage power distribution grid.
title Secure estimator design for Lur'e-type systems with nonuniformly and synchronously sampled measurements under attacks [extended version]
topic Optimization and Control
url https://arxiv.org/abs/2604.23217