Optimal robust fault-detection filter for micro-electro-mechanical system-based inertial navigation system/global positioning system

J. Shi; L. Miao; M. Ni; J. Shen

doi:10.1049/iet-cta.2010.0639

Optimal robust fault-detection filter for micro-electro-mechanical system-based inertial navigation system/global positioning system

J. Shi^*
, L. Miao
, M. Ni
, J. Shen

^*Corresponding author for this work

School of Automation

Northwestern Polytechnical University Xian
CAS - Beijing Institute of Control Engineering
Beijing Institute of Technology

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

18 Citations (Scopus)

Abstract

Since any disturbances and faults may lead to significant performance degradation in practical dynamical systems, it is essential for a system to be robust to disturbances and, at the same time, sensitive to faults. For this purpose, the authors propose an optimal robust fault-detection filter for linear discrete time-varying systems. The algorithm solves linear matrix inequalities to obtain the optimal robust H _∞ estimator, minimises the H _∞ norm from uncertain disturbances to estimation errors and uses H _- index to maximise the minimum effect of faults on the residual output of the filter. This approach is applied to the micro-electro-mechanical system-based inertial navigation system/global positioning system; and the simulation results show that the new algorithm can achieve small estimation errors and has high sensitivity to faults.

Original language	English
Pages (from-to)	254-260
Number of pages	7
Journal	IET Control Theory and Applications
Volume	6
Issue number	2
DOIs	https://doi.org/10.1049/iet-cta.2010.0639
Publication status	Published - 19 Jan 2012

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AU - Ni, M.

AU - Shen, J.

PY - 2012/1/19

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N2 - Since any disturbances and faults may lead to significant performance degradation in practical dynamical systems, it is essential for a system to be robust to disturbances and, at the same time, sensitive to faults. For this purpose, the authors propose an optimal robust fault-detection filter for linear discrete time-varying systems. The algorithm solves linear matrix inequalities to obtain the optimal robust H ∞ estimator, minimises the H ∞ norm from uncertain disturbances to estimation errors and uses H - index to maximise the minimum effect of faults on the residual output of the filter. This approach is applied to the micro-electro-mechanical system-based inertial navigation system/global positioning system; and the simulation results show that the new algorithm can achieve small estimation errors and has high sensitivity to faults.

AB - Since any disturbances and faults may lead to significant performance degradation in practical dynamical systems, it is essential for a system to be robust to disturbances and, at the same time, sensitive to faults. For this purpose, the authors propose an optimal robust fault-detection filter for linear discrete time-varying systems. The algorithm solves linear matrix inequalities to obtain the optimal robust H ∞ estimator, minimises the H ∞ norm from uncertain disturbances to estimation errors and uses H - index to maximise the minimum effect of faults on the residual output of the filter. This approach is applied to the micro-electro-mechanical system-based inertial navigation system/global positioning system; and the simulation results show that the new algorithm can achieve small estimation errors and has high sensitivity to faults.

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Optimal robust fault-detection filter for micro-electro-mechanical system-based inertial navigation system/global positioning system

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