Nonfragile fault‐tolerant control of suspension systems subject to input quantization and actuator fault

Summary This study addresses the quantized nonfragile feedback control problem for active suspension systems with and without actuator faults. By considering the input quantization, a class of dynamic quantizers is adopted. The multiplicative controller gain variation is used to describe the actuato...

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Published inInternational journal of robust and nonlinear control Vol. 30; no. 16; pp. 6720 - 6743
Main Authors Xiong, Jun, Chang, Xiao‐Heng, Park, Ju H., Li, Zhi‐Min
Format Journal Article
LanguageEnglish
Published Bognor Regis Wiley Subscription Services, Inc 10.11.2020
Subjects
Active control
active suspension
Actuators
Control systems
Controllers
Counters
Feedback control
input quantization
Measurement
nonfragile fault‐tolerant control
Output feedback
Parameter uncertainty
Passenger comfort
Perturbation
Redundancy
State feedback
static output feedback
Suspension systems
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Abstract Summary This study addresses the quantized nonfragile feedback control problem for active suspension systems with and without actuator faults. By considering the input quantization, a class of dynamic quantizers is adopted. The multiplicative controller gain variation is used to describe the actuator parameter perturbation or uncertainty. Apart from the ride comfort, the road holding ability and the hard constraints on suspension deflection and actuator force are also taken into account, which can be treated as a multi‐objective control problem. The redundancy of input quantization error is used to formulate the quantized closed‐loop system via the descriptor representation approach, then a novel quantized control strategy based on state feedback by separately designing dynamic quantizer and controller is proposed for the closed‐loop system with and without actuator faults. The design strategy is a unified and simple one, then can be easily extended to the case of static output feedback, as only part of the variables measured by sensors are available, which avoids some equality constraints in existing works. Finally, some simulation results are presented to validate the feasibility and effectiveness of the developed control strategies.
AbstractList This study addresses the quantized nonfragile feedback control problem for active suspension systems with and without actuator faults. By considering the input quantization, a class of dynamic quantizers is adopted. The multiplicative controller gain variation is used to describe the actuator parameter perturbation or uncertainty. Apart from the ride comfort, the road holding ability and the hard constraints on suspension deflection and actuator force are also taken into account, which can be treated as a multi‐objective control problem. The redundancy of input quantization error is used to formulate the quantized closed‐loop system via the descriptor representation approach, then a novel quantized control strategy based on state feedback by separately designing dynamic quantizer and controller is proposed for the closed‐loop system with and without actuator faults. The design strategy is a unified and simple one, then can be easily extended to the case of static output feedback, as only part of the variables measured by sensors are available, which avoids some equality constraints in existing works. Finally, some simulation results are presented to validate the feasibility and effectiveness of the developed control strategies.
Summary This study addresses the quantized nonfragile feedback control problem for active suspension systems with and without actuator faults. By considering the input quantization, a class of dynamic quantizers is adopted. The multiplicative controller gain variation is used to describe the actuator parameter perturbation or uncertainty. Apart from the ride comfort, the road holding ability and the hard constraints on suspension deflection and actuator force are also taken into account, which can be treated as a multi‐objective control problem. The redundancy of input quantization error is used to formulate the quantized closed‐loop system via the descriptor representation approach, then a novel quantized control strategy based on state feedback by separately designing dynamic quantizer and controller is proposed for the closed‐loop system with and without actuator faults. The design strategy is a unified and simple one, then can be easily extended to the case of static output feedback, as only part of the variables measured by sensors are available, which avoids some equality constraints in existing works. Finally, some simulation results are presented to validate the feasibility and effectiveness of the developed control strategies.
Author Park, Ju H.
Li, Zhi‐Min
Chang, Xiao‐Heng
Xiong, Jun
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  fullname: Xiong, Jun
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  orcidid: 0000-0002-6197-1623
  surname: Chang
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  orcidid: 0000-0002-0218-2333
  surname: Park
  fullname: Park, Ju H.
  email: jessie@ynu.ac.kr
  organization: Yeungnam University
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  givenname: Zhi‐Min
  surname: Li
  fullname: Li, Zhi‐Min
  organization: North China Institute of Aerospace Engineering
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Snippet Summary This study addresses the quantized nonfragile feedback control problem for active suspension systems with and without actuator faults. By considering...
This study addresses the quantized nonfragile feedback control problem for active suspension systems with and without actuator faults. By considering the input...
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SubjectTerms Active control
active suspension
Actuators
Control systems
Controllers
Counters
Feedback control
input quantization
Measurement
nonfragile fault‐tolerant control
Output feedback
Parameter uncertainty
Passenger comfort
Perturbation
Redundancy
State feedback
static output feedback
Suspension systems
Title Nonfragile fault‐tolerant control of suspension systems subject to input quantization and actuator fault
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Frnc.5135
https://www.proquest.com/docview/2448479244
Volume 30
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