Robust fault diagnosis of disturbed linear systems via a sliding mode high order differentiator

Francisco Javier Bejarano; Maricela Figueroa; Jaime Pacheco; José De Jesus Rubio

doi:10.1080/00207179.2012.661463

Robust fault diagnosis of disturbed linear systems via a sliding mode high order differentiator

Francisco Javier Bejarano, Maricela Figueroa, Jaime Pacheco, José De Jesus Rubio

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

14 Scopus citations

Abstract

A fault estimator for linear systems affected by disturbances is proposed. Faults appearing explicitly in the state equation and in the system output (actuator faults and sensor faults) are considered. With this design neither the estimation of the state vector nor the estimation of the disturbances is required, implying that the structural conditions are less restrictive than the ones required to design an unknown input observer. Furthermore, the number of unknown inputs (faults plus disturbances) may be greater than the number of outputs. The faults are written as an algebraic expression of a high-order derivative of a function depending on the output. Thus, the reconstruction of the fault signals is carried out by means of a sliding mode high-order differentiator, which requires the derivative of the faults to have a bounded norm.

Original language	English
Pages (from-to)	648-659
Number of pages	12
Journal	International Journal of Control
Volume	85
Issue number	6
DOIs	https://doi.org/10.1080/00207179.2012.661463
State	Published - 1 Jun 2012

Keywords

disturbed systems
fault detection and isolation
high-order sliding modes
robust control

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abstract = "A fault estimator for linear systems affected by disturbances is proposed. Faults appearing explicitly in the state equation and in the system output (actuator faults and sensor faults) are considered. With this design neither the estimation of the state vector nor the estimation of the disturbances is required, implying that the structural conditions are less restrictive than the ones required to design an unknown input observer. Furthermore, the number of unknown inputs (faults plus disturbances) may be greater than the number of outputs. The faults are written as an algebraic expression of a high-order derivative of a function depending on the output. Thus, the reconstruction of the fault signals is carried out by means of a sliding mode high-order differentiator, which requires the derivative of the faults to have a bounded norm.",

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AU - Bejarano, Francisco Javier

AU - Figueroa, Maricela

AU - Pacheco, Jaime

AU - De Jesus Rubio, José

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N2 - A fault estimator for linear systems affected by disturbances is proposed. Faults appearing explicitly in the state equation and in the system output (actuator faults and sensor faults) are considered. With this design neither the estimation of the state vector nor the estimation of the disturbances is required, implying that the structural conditions are less restrictive than the ones required to design an unknown input observer. Furthermore, the number of unknown inputs (faults plus disturbances) may be greater than the number of outputs. The faults are written as an algebraic expression of a high-order derivative of a function depending on the output. Thus, the reconstruction of the fault signals is carried out by means of a sliding mode high-order differentiator, which requires the derivative of the faults to have a bounded norm.

AB - A fault estimator for linear systems affected by disturbances is proposed. Faults appearing explicitly in the state equation and in the system output (actuator faults and sensor faults) are considered. With this design neither the estimation of the state vector nor the estimation of the disturbances is required, implying that the structural conditions are less restrictive than the ones required to design an unknown input observer. Furthermore, the number of unknown inputs (faults plus disturbances) may be greater than the number of outputs. The faults are written as an algebraic expression of a high-order derivative of a function depending on the output. Thus, the reconstruction of the fault signals is carried out by means of a sliding mode high-order differentiator, which requires the derivative of the faults to have a bounded norm.

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Robust fault diagnosis of disturbed linear systems via a sliding mode high order differentiator

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