Design of remotely located and multi-loop vibration controllers using a sequential loop closing approach
Design of remotely located and multi-loop vibration controllers using a sequential loop closing approach
In some applications, vibration control objectives may require reduction of levels at locations where control system components cannot be sited due to space or environmental considerations. Control actuators and error sensors for such a scenario will need to be placed at appropriate locations which are potentially remote from the points where ultimate attenuation is desired. The performance of the closed loop system, therefore, cannot be assessed simply by the measurement obtained at this local error sensor. The control design objective has to take into account the vibration levels at the remote locations as well. A design methodology was recently proposed that tackles such problems using a single-loop feedback control architecture. The work in this paper describes an extension of this control design procedure to enable the systematic design of multiple decentralised control loops. The approach is based upon sequential loop closing and conditions are provided that ensure that closed loop stability is maintained even in the event of failure in some control loops. The design procedure is illustrated through its application to a laboratory scale slab floor that replicates the problems associated with human induced vibration in large open-plan office buildings. The experimental results demonstrate the efficacy of the approach and significant suppression of the dominant low frequency modes in the floor is achieved using two independent acceleration feedback control loops
1-10
Ubaid, Ubaid
6eea8cf9-7ee6-4adb-b606-50c4d66f9caf
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Pope, S.A.
b0b4819d-9c21-4bae-8961-6c91796b78a5
May 2015
Ubaid, Ubaid
6eea8cf9-7ee6-4adb-b606-50c4d66f9caf
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Pope, S.A.
b0b4819d-9c21-4bae-8961-6c91796b78a5
Ubaid, Ubaid, Daley, Stephen and Pope, S.A.
(2015)
Design of remotely located and multi-loop vibration controllers using a sequential loop closing approach.
Control Engineering Practice, 38, .
(doi:10.1016/j.conengprac.2014.12.016).
Abstract
In some applications, vibration control objectives may require reduction of levels at locations where control system components cannot be sited due to space or environmental considerations. Control actuators and error sensors for such a scenario will need to be placed at appropriate locations which are potentially remote from the points where ultimate attenuation is desired. The performance of the closed loop system, therefore, cannot be assessed simply by the measurement obtained at this local error sensor. The control design objective has to take into account the vibration levels at the remote locations as well. A design methodology was recently proposed that tackles such problems using a single-loop feedback control architecture. The work in this paper describes an extension of this control design procedure to enable the systematic design of multiple decentralised control loops. The approach is based upon sequential loop closing and conditions are provided that ensure that closed loop stability is maintained even in the event of failure in some control loops. The design procedure is illustrated through its application to a laboratory scale slab floor that replicates the problems associated with human induced vibration in large open-plan office buildings. The experimental results demonstrate the efficacy of the approach and significant suppression of the dominant low frequency modes in the floor is achieved using two independent acceleration feedback control loops
Text
CEP_Multi_Loop_Final.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 31 December 2014
e-pub ahead of print date: 4 February 2015
Published date: May 2015
Organisations:
Signal Processing & Control Grp
Identifiers
Local EPrints ID: 374133
URI: http://eprints.soton.ac.uk/id/eprint/374133
ISSN: 0967-0661
PURE UUID: 2c4b8410-f8ba-426d-b853-f4868d41bf33
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Date deposited: 06 Feb 2015 11:34
Last modified: 14 Mar 2024 19:02
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Author:
Ubaid Ubaid
Author:
S.A. Pope
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