Experimental study of wireless structural vibration control considering different time delays

Yu, Yan; Guo, J. C.; Li, Luyu; Song, Gangbing; Ou, Jinping

doi:10.1088/0964-1726/24/4/045005

Cited by 11 publications

(4 citation statements)

References 22 publications

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“…Conversely, the geometry of the piezoelectric material will deform according to the applied electrical field [ 31 , 32 , 33 ]. The direct effect of the piezoelectric material can be utilized for sensing [ 34 , 35 ], energy harvesting [ 36 , 37 , 38 , 39 , 40 ], or passive vibration damping [ 41 , 42 , 43 , 44 ], and the converse effect can be used as actuators [ 45 , 46 , 47 , 48 ]. Owing to their unique property of dual sensing and actuating ability, high bandwidth [ 49 ], and low cost, piezoelectric materials are frequently used in the SHM field as transducers.…”

Section: The Transducers Used In Bond-slip Monitoringmentioning

confidence: 99%

Bond-Slip Monitoring of Concrete Structures Using Smart Sensors—A Review

Huo

Cheng

Kong

et al. 2019

Sensors

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Concrete structures with various reinforcements, such as steel bars, composite material tendons, and recently steel plates, are commonly used in civil infrastructures. When an external force overcomes the strength of the bond between the reinforcement and the concrete, bond-slip will occur, resulting in a relative displacement between the reinforcing materials and the concrete. Monitoring bond health plays an important role in guaranteeing structural safety. Recently, researchers have recognized the importance of bond-slip monitoring and performed many related investigations. In this paper, a state-of-the-art review on various smart sensors based on piezoelectric effect and fiber optic technology, as well as corresponding techniques for bond-slip monitoring is presented. Since piezoelectric sensors and fiber-optic sensors are widely used in bond-slip monitoring, their principles and relevant monitoring methods are also introduced in this paper. Particularly, the piezoelectric-based bond-slip monitoring methods including the active sensing method, the electro-mechanical impedance (EMI) method and the passive sensing using acoustic emission (AE) method, and the fiber-optic-based bond-slip detecting approaches including the fiber Bragg grating (FBG) and the distributed fiber optic sensing are highlighted. This paper provides guidance for practical applications and future development of bond-slip monitoring.

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Section: The Transducers Used In Bond-slip Monitoringmentioning

confidence: 99%

Bond-Slip Monitoring of Concrete Structures Using Smart Sensors—A Review

Huo

Cheng

Kong

et al. 2019

Sensors

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“…Second-order differential equations arise in several system modeling, such as electrical, electromechanical, and mechanical systems. Also, they are commonly used in structural, vibration, multi-body systems, and robotic modeling and control [1][2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Dynamic Output Feedback of Second-Order Systems: An Observer-Based Controller with Linear Matrix Inequality Design

Gontijo,

Araújo,

Frezzato

et al. 2024

Actuators

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This paper presents an observer-based dynamic output-feedback controller design procedure using linear matrix inequality (LMI) optimization for second-order systems with uncertainty and persistent perturbation in the states. Using linear-quadratic criteria, cost functions are minimized in a two-stage procedure to compute optimal state-feedback gains, and observer gains are coupled into a dynamic output-feedback optimal controller. The LMI set used in the two stages is matrix inversion free, a key issue for polytope formulation when uncertainty is present. The approach is tested in a mobile inverted pendulum robotic platform, and the effectiveness is verified in this underactuated and undesensed case.

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“…In recent decades, the vibration control strategy has been an efficient and a safe approach to protect civil structures against strong environmental excitations (Amini and Karami, 2011). Important challenges in this research area, which have been studied a lot in the literature, include the unpredictability of inputs (for instance, earthquake and wind), difficulty and complexity of the real-time measurement of input excitations (Yu et al, 2015), the limitation of sensor numbers to identify the system (Abazarsa et al, 2013;Amini and Karami, 2012;Mesquita et al, 2016;Nagarajaiah and Erazo, 2016;Yang and Nagarajaiah, 2013;Yao et al, 2018), the uncertainty in system information (Amini et al, 2017;Giaralis and Taflanidis, 2018;Huo et al, 2016;Nguyen et al, 2018), the computation time required in controllers (Gutierrez Soto and Adeli, 2017), and the time delay in generating forces by control devices (Chae et al, 2013;Chen et al, 2017;Morales-Beltran and Paul, 2015;Shao and Chen, 2013;Shen et al, 2013;Spencer and Nagarajaiah, 2003;Khoshbin et al, 2018). Moving to create a smart structure is developing at a rapid pace due to the evolution of smart devices, actuators, control strategies, novel designs, and calculation tools.…”

Section: Introductionmentioning

confidence: 99%

Seismic motion control of structures using an adaptive optimal model-free controller

Sourni

Batmani

Karami

2020

Journal of Vibration and Control

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One of the major challenges in the real-time control of structures is the uncertainty in identifying the mechanical properties of the system, including mass, stiffness, and damping. However, the presence of uncertainty in time-varying systems (under severe environmental factors, the dynamic characteristics of the system change due to damage) is more noticeable. In this article, to deal with the problem of parametric uncertainties in seismic motion control of structures, an adaptive optimal controller is applied. The design procedure of the controller is straightforward, and there is no need to have the values of the structural parameters. In the proposed scheme, only the states of the system are measured, and it is not necessary to use the ground acceleration data which are difficult to be measured in real time. It is shown that the performance of the designed controller converges to the well-known linear quadratic regulator. Simulation results reveal that considerable reductions of the dynamic responses during the earthquakes are achieved using the utilized adaptive optimal controller, and also it is robust against any variation in the structural parameters due to the damages.

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Experimental study of wireless structural vibration control considering different time delays

Cited by 11 publications

References 22 publications

Bond-Slip Monitoring of Concrete Structures Using Smart Sensors—A Review

Bond-Slip Monitoring of Concrete Structures Using Smart Sensors—A Review

Dynamic Output Feedback of Second-Order Systems: An Observer-Based Controller with Linear Matrix Inequality Design

Seismic motion control of structures using an adaptive optimal model-free controller

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