Online control of an active seismic system via reinforcement learning

Khalatbarisoltani, Arash; Soleymani, Mehdi; Khodadadi, M.

doi:10.1002/stc.2298

Cited by 29 publications

(14 citation statements)

References 51 publications

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“…From Table 7i, it can be concluded that the structural performance evaluations in mitigation applications usually used ML as a regression model while RL was typically utilized as an effective optimization or control algorithm. It is noted that relatively few ML applications for structural optimization and control under winds have been generated compared to those in earthquake engineering community (e.g., Ghaboussi and Joghataie 1995;Adam and Smith 2008;Jiang and Adeli 2008;Yakut and Alli 2011;Subasri et al, 2014;Khodabandehlou et al, 2018;Khalatbarisoltani et al, 2019;Hayashi and Ohsaki 2020). From Table 7ii, it can be concluded that most social media-informed response applications used ML as a classification model for disaster rescue and relief information dissemination.…”

Section: Mitigation and Responsementioning

confidence: 99%

Applications of Machine Learning to Wind Engineering

Snaiki

2022

Front. Built Environ.

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Advances of the analytical, numerical, experimental and field-measurement approaches in wind engineering offers unprecedented volume of data that, together with rapidly evolving learning algorithms and high-performance computational hardware, provide an opportunity for the community to embrace and harness full potential of machine learning (ML). This contribution examines the state of research and practice of ML for its applications to wind engineering. In addition to ML applications to wind climate, terrain/topography, aerodynamics/aeroelasticity and structural dynamics (following traditional Alan G. Davenport Wind Loading Chain), the review also extends to cover wind damage assessment and wind-related hazard mitigation and response (considering emerging performance-based and resilience-based wind design methodologies). This state-of-the-art review suggests to what extend ML has been utilized in each of these topic areas within wind engineering and provides a comprehensive summary to improve understanding how learning algorithms work and when these schemes succeed or fail. Moreover, critical challenges and prospects of ML applications in wind engineering are identified to facilitate future research efforts.

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Section: Mitigation and Responsementioning

confidence: 99%

Applications of Machine Learning to Wind Engineering

Snaiki

2022

Front. Built Environ.

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“…The existing literature focuses on developing ANN models in active and semi-active control, while more advanced learning algorithms, such as reinforcement learning (Khalatbarisoltani et al, 2019), should be explored to realize robust control in tackling various sources of uncertainties simultaneously, including seismic uncertainties and time delays. Meanwhile, the promise of implementing ML in structural control can be enhanced if other forms of control devices are investigated, such as active tuned mass damper, distributed actuators, and semi-active stiffness dampers (Fisco and Adeli, 2011).…”

Section: Structural Control For Earthquake Mitigationmentioning

confidence: 99%

The promise of implementing machine learning in earthquake engineering: A state-of-the-art review

et al. 2020

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Machine learning (ML) has evolved rapidly over recent years with the promise to substantially alter and enhance the role of data science in a variety of disciplines. Compared with traditional approaches, ML offers advantages to handle complex problems, provide computational efficiency, propagate and treat uncertainties, and facilitate decision making. Also, the maturing of ML has led to significant advances in not only the main-stream artificial intelligence (AI) research but also other science and engineering fields, such as material science, bioengineering, construction management, and transportation engineering. This study conducts a comprehensive review of the progress and challenges of implementing ML in the earthquake engineering domain. A hierarchical attribute matrix is adopted to categorize the existing literature based on four traits identified in the field, such as ML method, topic area, data resource, and scale of analysis. The state-of-the-art review indicates to what extent ML has been applied in four topic areas of earthquake engineering, including seismic hazard analysis, system identification and damage detection, seismic fragility assessment, and structural control for earthquake mitigation. Moreover, research challenges and the associated future research needs are discussed, which include embracing the next generation of data sharing and sensor technologies, implementing more advanced ML techniques, and developing physics-guided ML models.

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“…A state predictor is combined with proposed controller to solve the time delay problem. 9 Chen and Lai have combined a transfer system with a modern control strategy for shaking tables in order to mimicking the responses of high-rise buildings subjected to earthquakes. Three nonlinear controllers and three linear controllers are designed and synthesized to verify the feasibility and applicability of the proposed strategy.…”

Section: Introductionmentioning

confidence: 99%

Adaptive backstepping sliding mode control design for vibration suppression of earth-quaked building supported by magneto-rheological damper

Humaidi¹,

Sadiq²,

Abdulkareem³

et al. 2021

Journal of Low Frequency Noise, Vibration and Active Control

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In this study, the design of adaptive backstepping sliding mode control (ABSMC) has been developed for vibration suppression of earth-quaked building supported by magneto-rheological (MR) damper. The control and adaptive laws developed based on ABSMC methodology has been established according to stability analysis based on Lyupunov theorem. A Single degree of freedom (SDOF) building system has been considered and the earthquake acceleration data used in performance analysis of the proposed controller is based on El Centro Imperial Valley Earthquake. The ABSMC has been compared to classical sliding mode control in terms of vibration suppression in the controlled system subjected to earthquake. The performance of proposed controller has been assessed via computer simulation, which showed its effectiveness to stabilize the building against earthquake vibration and the boundness of estimated stiffness and viscosity coefficients.

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Online control of an active seismic system via reinforcement learning

Cited by 29 publications

References 51 publications

Applications of Machine Learning to Wind Engineering

Applications of Machine Learning to Wind Engineering

The promise of implementing machine learning in earthquake engineering: A state-of-the-art review

Adaptive backstepping sliding mode control design for vibration suppression of earth-quaked building supported by magneto-rheological damper

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