Closed-loop analysis and control of cavity shear layer oscillations

Mohamed Yazid Rizi; Luc Pastur; Mohamed Abbas-Turki; Yann Fraigneau; Hisham Abou-Kandil

doi:10.1260/1756-8250.6.4.171

Closed-loop analysis and control of cavity shear layer oscillations

Mohamed Yazid Rizi, Luc Pastur, Mohamed Abbas-Turki, Yann Fraigneau, Hisham Abou-Kandil

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

Abstract

This paper focuses on the closed-loop control of an incompressible flow past an open cavity. We propose a delayed feedback controller to suppress the self-sustained oscillations of the shear layer. The control law shows robustness to changes in flow conditions. An extension of the Eigensystem Realization Algorithm (ERA) to closed-loop identification, the so-called OCID technique, is used to extract the unstable linear dynamics of the cavity flow. The model-based analysis actually captures the modes against which the steady flow becomes unstable. The identified model is used to design an optimal controller, which shows both efficiency and robustness to stabilize the cavity flow.

Original language	English
Pages (from-to)	171-187
Number of pages	17
Journal	International Journal of Flow Control
Volume	6
Issue number	4
DOIs	https://doi.org/10.1260/1756-8250.6.4.171
Publication status	Published - 1 Dec 2014
Externally published	Yes

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title = "Closed-loop analysis and control of cavity shear layer oscillations",

abstract = "This paper focuses on the closed-loop control of an incompressible flow past an open cavity. We propose a delayed feedback controller to suppress the self-sustained oscillations of the shear layer. The control law shows robustness to changes in flow conditions. An extension of the Eigensystem Realization Algorithm (ERA) to closed-loop identification, the so-called OCID technique, is used to extract the unstable linear dynamics of the cavity flow. The model-based analysis actually captures the modes against which the steady flow becomes unstable. The identified model is used to design an optimal controller, which shows both efficiency and robustness to stabilize the cavity flow.",

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AU - Rizi, Mohamed Yazid

AU - Pastur, Luc

AU - Abbas-Turki, Mohamed

AU - Fraigneau, Yann

AU - Abou-Kandil, Hisham

PY - 2014/12/1

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N2 - This paper focuses on the closed-loop control of an incompressible flow past an open cavity. We propose a delayed feedback controller to suppress the self-sustained oscillations of the shear layer. The control law shows robustness to changes in flow conditions. An extension of the Eigensystem Realization Algorithm (ERA) to closed-loop identification, the so-called OCID technique, is used to extract the unstable linear dynamics of the cavity flow. The model-based analysis actually captures the modes against which the steady flow becomes unstable. The identified model is used to design an optimal controller, which shows both efficiency and robustness to stabilize the cavity flow.

AB - This paper focuses on the closed-loop control of an incompressible flow past an open cavity. We propose a delayed feedback controller to suppress the self-sustained oscillations of the shear layer. The control law shows robustness to changes in flow conditions. An extension of the Eigensystem Realization Algorithm (ERA) to closed-loop identification, the so-called OCID technique, is used to extract the unstable linear dynamics of the cavity flow. The model-based analysis actually captures the modes against which the steady flow becomes unstable. The identified model is used to design an optimal controller, which shows both efficiency and robustness to stabilize the cavity flow.

U2 - 10.1260/1756-8250.6.4.171

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EP - 187

JO - International Journal of Flow Control

JF - International Journal of Flow Control

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ER -

Closed-loop analysis and control of cavity shear layer oscillations

Abstract

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