Experimental Validation of Ellipsoidal Techniques for State Estimation in Marine Applications

Andreas Rauh; Yohann Gourret; Katell Lagattu; Bernardo Hummes; Luc Jaulin; Johannes Reuter; Stefan Wirtensohn; Patrick Hoher

doi:10.3390/a15050162

Experimental Validation of Ellipsoidal Techniques for State Estimation in Marine Applications

Andreas Rauh, Yohann Gourret, Katell Lagattu, Bernardo Hummes, Luc Jaulin, Johannes Reuter, Stefan Wirtensohn, Patrick Hoher

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Abstract

A reliable quantification of the worst-case influence of model uncertainty and external disturbances is crucial for the localization of vessels in marine applications. This is especially true if uncertain GPS-based position measurements are used to update predicted vessel locations that are obtained from the evaluation of a ship’s state equation. To reflect real-life working conditions, these state equations need to account for uncertainty in the system model, such as imperfect actuation and external disturbances due to effects such as wind and currents. As an application scenario, the GPS-based localization of autonomous DDboat robots is considered in this paper. Using experimental data, the efficiency of an ellipsoidal approach, which exploits a bounded-error representation of disturbances and uncertainties, is demonstrated.

Original language	English
Article number	162
Number of pages	23
Journal	Algorithms
Volume	15
Issue number	5
DOIs	https://doi.org/10.3390/a15050162
Publication status	Published - May 2022
Externally published	Yes

Keywords

bounded uncertainty
ellipsoidal enclosures
state and disturbance estimation
uncertainty modeling

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10.3390/a15050162Licence: CC BY

Final published versionFinal published version, 6.67 MBLicence: CC BY

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title = "Experimental Validation of Ellipsoidal Techniques for State Estimation in Marine Applications",

abstract = "A reliable quantification of the worst-case influence of model uncertainty and external disturbances is crucial for the localization of vessels in marine applications. This is especially true if uncertain GPS-based position measurements are used to update predicted vessel locations that are obtained from the evaluation of a ship{\textquoteright}s state equation. To reflect real-life working conditions, these state equations need to account for uncertainty in the system model, such as imperfect actuation and external disturbances due to effects such as wind and currents. As an application scenario, the GPS-based localization of autonomous DDboat robots is considered in this paper. Using experimental data, the efficiency of an ellipsoidal approach, which exploits a bounded-error representation of disturbances and uncertainties, is demonstrated.",

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AU - Rauh, Andreas

AU - Gourret, Yohann

AU - Lagattu, Katell

AU - Hummes, Bernardo

AU - Jaulin, Luc

AU - Reuter, Johannes

AU - Wirtensohn, Stefan

AU - Hoher, Patrick

PY - 2022/5

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N2 - A reliable quantification of the worst-case influence of model uncertainty and external disturbances is crucial for the localization of vessels in marine applications. This is especially true if uncertain GPS-based position measurements are used to update predicted vessel locations that are obtained from the evaluation of a ship’s state equation. To reflect real-life working conditions, these state equations need to account for uncertainty in the system model, such as imperfect actuation and external disturbances due to effects such as wind and currents. As an application scenario, the GPS-based localization of autonomous DDboat robots is considered in this paper. Using experimental data, the efficiency of an ellipsoidal approach, which exploits a bounded-error representation of disturbances and uncertainties, is demonstrated.

AB - A reliable quantification of the worst-case influence of model uncertainty and external disturbances is crucial for the localization of vessels in marine applications. This is especially true if uncertain GPS-based position measurements are used to update predicted vessel locations that are obtained from the evaluation of a ship’s state equation. To reflect real-life working conditions, these state equations need to account for uncertainty in the system model, such as imperfect actuation and external disturbances due to effects such as wind and currents. As an application scenario, the GPS-based localization of autonomous DDboat robots is considered in this paper. Using experimental data, the efficiency of an ellipsoidal approach, which exploits a bounded-error representation of disturbances and uncertainties, is demonstrated.

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Experimental Validation of Ellipsoidal Techniques for State Estimation in Marine Applications

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Keywords

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