Optimal negative derivative feedback controller design for collocated systems based on H2 and H∞ method

•A straightforward design method for Negative Derivative Feedback Controller.•Optimal design of NDF controller with the maximum possible closed loop damping.•Applicable for collocated system with different patterns (zero before pole or zero after pole pattern).•Acting as a bandpass filter, cutting o...

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Veröffentlicht in:	Mechanical systems and signal processing Jg. 181; S. 109497
Hauptverfasser:	Jamshidi, Rasa, Collette, Christophe
Format:	Journal Article
Sprache:	Englisch
Veröffentlicht:	Elsevier Ltd 01.12.2022 Elsevier BV
Schlagworte:	Aerospace Engineering Band-pass filter Civil and Structural Engineering Collocated system Computer Science Applications Control and Systems Engineering Engineering, computing & technology Ingénierie mécanique Ingénierie, informatique & technologie Maximum damping Mechanical Engineering Negative derivative feedback (NDF) Pole-zero pattern Signal Processing Vibration mitigation Maximum damping Vibration mitigation Collocated system Band-pass filter Pole-zero pattern Negative derivative feedback (NDF)
ISSN:	0888-3270, 1096-1216, 1096-1216
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Abstract	•A straightforward design method for Negative Derivative Feedback Controller.•Optimal design of NDF controller with the maximum possible closed loop damping.•Applicable for collocated system with different patterns (zero before pole or zero after pole pattern).•Acting as a bandpass filter, cutting off the control action far from the controlled modes which reduces the spillover effect.•Using different strategies for finding optimal solution (H2 and H∞). In this paper, a direct procedure is presented in order to design negative derivative feedback (NDF) controller for collocated systems. Collocated systems have embedded sensors and actuators, which have an alternating poles and zeroes in frequency domain, which creates asymptotic stability. NDF is a band-pass filter, cutting off the control action far from the natural frequencies associated with the controlled modes, which reduces the spillover effect. Since it is a band-pass filter, it can effectively control the lower and higher frequency disturbances. Also, it is very efficient controller for higher frequencies’ vibration mitigation. An approach for an optimal design of NDF controller to implement on collocated system is presented. A simple, collocated system is considered and a mode of it is targeted to damp. Maximum damping method is used to extract all of the controller constants dependent on closed-loop damping value. Afterward, H2 and H∞ methods are utilized to determine the closed-loop damping value optimally. The results show that NDF not only can easily damp the targeted mode impactfully but also can reduce some level of vibrations in the modes after that as well. This shows the power of NDF filter on vibration mitigation of modes located in a band of frequency. The proposed method is applicable for any general system and for any zero/pole patterns of collocated system, easily. It can be applied for any collocated system with zero before pole pattern or zero after pole pattern.
AbstractList	•A straightforward design method for Negative Derivative Feedback Controller.•Optimal design of NDF controller with the maximum possible closed loop damping.•Applicable for collocated system with different patterns (zero before pole or zero after pole pattern).•Acting as a bandpass filter, cutting off the control action far from the controlled modes which reduces the spillover effect.•Using different strategies for finding optimal solution (H2 and H∞). In this paper, a direct procedure is presented in order to design negative derivative feedback (NDF) controller for collocated systems. Collocated systems have embedded sensors and actuators, which have an alternating poles and zeroes in frequency domain, which creates asymptotic stability. NDF is a band-pass filter, cutting off the control action far from the natural frequencies associated with the controlled modes, which reduces the spillover effect. Since it is a band-pass filter, it can effectively control the lower and higher frequency disturbances. Also, it is very efficient controller for higher frequencies’ vibration mitigation. An approach for an optimal design of NDF controller to implement on collocated system is presented. A simple, collocated system is considered and a mode of it is targeted to damp. Maximum damping method is used to extract all of the controller constants dependent on closed-loop damping value. Afterward, H2 and H∞ methods are utilized to determine the closed-loop damping value optimally. The results show that NDF not only can easily damp the targeted mode impactfully but also can reduce some level of vibrations in the modes after that as well. This shows the power of NDF filter on vibration mitigation of modes located in a band of frequency. The proposed method is applicable for any general system and for any zero/pole patterns of collocated system, easily. It can be applied for any collocated system with zero before pole pattern or zero after pole pattern.
ArticleNumber	109497
Author	Collette, Christophe Jamshidi, Rasa
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Keywords	Maximum damping Vibration mitigation Collocated system Band-pass filter Pole-zero pattern Negative derivative feedback (NDF)
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Snippet	•A straightforward design method for Negative Derivative Feedback Controller.•Optimal design of NDF controller with the maximum possible closed loop...
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SubjectTerms	Aerospace Engineering Band-pass filter Civil and Structural Engineering Collocated system Computer Science Applications Control and Systems Engineering Engineering, computing & technology Ingénierie mécanique Ingénierie, informatique & technologie Maximum damping Mechanical Engineering Negative derivative feedback (NDF) Pole-zero pattern Signal Processing Vibration mitigation
Title	Optimal negative derivative feedback controller design for collocated systems based on H2 and H∞ method
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