Robust Fault Estimation With Structured Uncertainty: Scalable Algorithms and Experimental Validation in Automated Vehicles

To increase system robustness and autonomy, in this article, we propose a nonlinear fault estimation filter for a class of linear dynamical systems, subject to structured uncertainty, measurement noise, and system delays, in the presence of additive and multiplicative faults. The proposed filter arc...

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Vydané v:IEEE transactions on control systems technology Ročník 33; číslo 5; s. 1651 - 1666
Hlavní autori: van der Ploeg, Chris, Vieira Oliveira, Pedro, Silvas, Emilia, Mohajerin Esfahani, Peyman, van de Wouw, Nathan
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: New York IEEE 01.09.2025
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Predmet:
Accuracy
Automated vehicles
Automation
Autonomous vehicles
convex optimization
Convexity
Data models
Delays
Dynamical systems
Estimation
Fault detection
fault estimation
Faults
model uncertainty
Noise
Noise measurement
Observers
Safety
Uncertainty
ISSN:1063-6536, 1558-0865
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Shrnutí:To increase system robustness and autonomy, in this article, we propose a nonlinear fault estimation filter for a class of linear dynamical systems, subject to structured uncertainty, measurement noise, and system delays, in the presence of additive and multiplicative faults. The proposed filter architecture combines tools from model-based control approaches, regression techniques, and convex optimization. The proposed method estimates the additive and multiplicative faults using a linear residual generator combined with nonlinear regression. An offline simulator allows us to numerically characterize the mismatch between an assumed linear model and a range of alternative linear models that exhibit different levels of structured uncertainty. Moreover, we show how the performance bounds of the estimator, valid in the absence of uncertainty, can be used to determine appropriate countermeasures for measurement noise. In the scope of this work, we focus particularly on a fault estimation problem for Society of Automotive Engineers (SAEs) level 4 automated vehicles, which must remain operational in various cases and cannot rely on the driver. The proposed approach is demonstrated in simulations and in an experimental setting, where it is shown that additive and multiplicative faults can be estimated in a real vehicle under the influence of model uncertainty, measurement noise, and delay.
Bibliografia:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 14
ISSN:1063-6536
1558-0865
DOI:10.1109/TCST.2025.3552618