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Linear control of oscillator and amplifier flows *

Linear control of oscillator and amplifier flows * Linear control applied to fluid systems near an equilibrium point has important applications for many flows of industrial or fundamental interest. In this article we give an exposition of tools and approaches for the design of control strategies for globally stable or unstable flows. For unstable oscillator flows a feedback configuration and a model-based approach is proposed, while for stable noise-amplifier flows a feedforward setup and an approach based on system identification is advocated. Model reduction and robustness issues are addressed for the oscillator case; statistical learning techniques are emphasized for the amplifier case. Effective suppression of global and convective instabilities could be demonstrated for either case, even though the system-identification approach results in a superior robustness to off-design conditions. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Physical Review Fluids American Physical Society (APS)

Linear control of oscillator and amplifier flows *

Schmid, Peter J.; Sipp, Denis
Physical Review Fluids , Volume 1 (4): 29 – Aug 30, 2016
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Linear control of oscillator and amplifier flows *

Schmid, Peter J.; Sipp, Denis
Physical Review Fluids , Volume 1 (4): 29 – Aug 30, 2016

Abstract

Linear control applied to fluid systems near an equilibrium point has important applications for many flows of industrial or fundamental interest. In this article we give an exposition of tools and approaches for the design of control strategies for globally stable or unstable flows. For unstable oscillator flows a feedback configuration and a model-based approach is proposed, while for stable noise-amplifier flows a feedforward setup and an approach based on system identification is advocated. Model reduction and robustness issues are addressed for the oscillator case; statistical learning techniques are emphasized for the amplifier case. Effective suppression of global and convective instabilities could be demonstrated for either case, even though the system-identification approach results in a superior robustness to off-design conditions.

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References (49)

Publisher
American Physical Society (APS)
Copyright
©2016 American Physical Society
Subject
INVITED ARTICLES; Invited Articles
ISSN
2469-990X
eISSN
2469-990X
DOI
10.1103/PhysRevFluids.1.040501
Publisher site
See Article on Publisher Site

Abstract

Linear control applied to fluid systems near an equilibrium point has important applications for many flows of industrial or fundamental interest. In this article we give an exposition of tools and approaches for the design of control strategies for globally stable or unstable flows. For unstable oscillator flows a feedback configuration and a model-based approach is proposed, while for stable noise-amplifier flows a feedforward setup and an approach based on system identification is advocated. Model reduction and robustness issues are addressed for the oscillator case; statistical learning techniques are emphasized for the amplifier case. Effective suppression of global and convective instabilities could be demonstrated for either case, even though the system-identification approach results in a superior robustness to off-design conditions.

Journal

Physical Review FluidsAmerican Physical Society (APS)

Published: Aug 30, 2016

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