Worst-Case Stealthy Attacks on Stochastic Event-Based State Estimation

Jun Shang; Hao Yu; Tongwen Chen

doi:10.1109/TAC.2021.3071948

Worst-Case Stealthy Attacks on Stochastic Event-Based State Estimation

Jun Shang, Hao Yu^*, Tongwen Chen

^*Corresponding author for this work

University of Alberta

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

18 Citations (Scopus)

Abstract

This article considers the worst-case stealthy attack strategies on stochastic event-based state estimation. Smart sensors equipped with local event-triggered Kalman filters are used to transmit innovations. Contrary to classic Kalman filters, the transmitted innovation screened by the stochastic decision rule does not follow a Gaussian distribution. A type of distribution called complete Gaussian crater is defined and analyzed, which is essential for designing stealthy attacks. The evolution of the estimation error covariance under attacks is obtained. Stealthy attacks that yield the greatest estimation errors under constraints on transmission rates and probability distributions are obtained and analyzed. The system performance degradation caused by different attacks is evaluated via simulations.

Original language	English
Pages (from-to)	2052-2059
Number of pages	8
Journal	IEEE Transactions on Automatic Control
Volume	67
Issue number	4
DOIs	https://doi.org/10.1109/TAC.2021.3071948
Publication status	Published - 1 Apr 2022
Externally published	Yes

Keywords

Communication rates
event-based sensor schedule
remote state estimation
stealthy attacks

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10.1109/TAC.2021.3071948

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abstract = "This article considers the worst-case stealthy attack strategies on stochastic event-based state estimation. Smart sensors equipped with local event-triggered Kalman filters are used to transmit innovations. Contrary to classic Kalman filters, the transmitted innovation screened by the stochastic decision rule does not follow a Gaussian distribution. A type of distribution called complete Gaussian crater is defined and analyzed, which is essential for designing stealthy attacks. The evolution of the estimation error covariance under attacks is obtained. Stealthy attacks that yield the greatest estimation errors under constraints on transmission rates and probability distributions are obtained and analyzed. The system performance degradation caused by different attacks is evaluated via simulations.",

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AB - This article considers the worst-case stealthy attack strategies on stochastic event-based state estimation. Smart sensors equipped with local event-triggered Kalman filters are used to transmit innovations. Contrary to classic Kalman filters, the transmitted innovation screened by the stochastic decision rule does not follow a Gaussian distribution. A type of distribution called complete Gaussian crater is defined and analyzed, which is essential for designing stealthy attacks. The evolution of the estimation error covariance under attacks is obtained. Stealthy attacks that yield the greatest estimation errors under constraints on transmission rates and probability distributions are obtained and analyzed. The system performance degradation caused by different attacks is evaluated via simulations.

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Worst-Case Stealthy Attacks on Stochastic Event-Based State Estimation

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Keywords

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