A geometric approach to the design of remotely located
vibration control systems
A geometric approach to the design of remotely located
vibration control systems
Over the past three decades, a wide variety of active control methods have been proposed for controlling problematic vibration. The vast majority of approaches make the implicit assumption that sensors can be located in the region where vibration attenuation is required. For many large scale structures or where the system environment is harsh, this is either not feasible or it is prohibitively expensive. As a result, the optimal control of local vibration may lead to enhancement at remote locations. Motivated by such problems in marine system environments, this paper describes a simple geometric methodology that provides an approach for defining the design freedom available for reducing vibration both at local and remote locations. The results can be used to develop design procedures for both discrete frequency and broad-band control. Robustness to modelling error can also be treated in the same geometric framework. Validation of the approach is carried out using an experimental facility that has been developed to replicate the problems associated with rotor blade vibration.
702-714
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Wang, Jiqiang
4f773100-474a-4c84-9ff2-43897af09855
23 December 2008
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Wang, Jiqiang
4f773100-474a-4c84-9ff2-43897af09855
Daley, Stephen and Wang, Jiqiang
(2008)
A geometric approach to the design of remotely located
vibration control systems.
Journal of Sound and Vibration, 318 (4-5), .
(doi:10.1016/j.jsv.2008.04.050).
Abstract
Over the past three decades, a wide variety of active control methods have been proposed for controlling problematic vibration. The vast majority of approaches make the implicit assumption that sensors can be located in the region where vibration attenuation is required. For many large scale structures or where the system environment is harsh, this is either not feasible or it is prohibitively expensive. As a result, the optimal control of local vibration may lead to enhancement at remote locations. Motivated by such problems in marine system environments, this paper describes a simple geometric methodology that provides an approach for defining the design freedom available for reducing vibration both at local and remote locations. The results can be used to develop design procedures for both discrete frequency and broad-band control. Robustness to modelling error can also be treated in the same geometric framework. Validation of the approach is carried out using an experimental facility that has been developed to replicate the problems associated with rotor blade vibration.
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Published date: 23 December 2008
Organisations:
Signal Processing & Control Group
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Local EPrints ID: 186743
URI: http://eprints.soton.ac.uk/id/eprint/186743
ISSN: 0022-460X
PURE UUID: 8a2b5160-d421-4923-83ad-e359dcec9792
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Date deposited: 16 May 2011 08:41
Last modified: 14 Mar 2024 03:21
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Author:
Jiqiang Wang
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