Integrated seismic early warning and structural health monitoring of critical civil infrastructures in seismically prone areas

Rainieri, Carlo; Fabbrocino, Giovanni; Cosenza, Edoardo

doi:10.1177/1475921710373296

Cited by 72 publications

(39 citation statements)

References 26 publications

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“…From the results of two case studies combining a realistic structural model and wireless simulations collected from real-world deployments, the authors concluded that both approaches improve structural control performance. Finally, Rainieri et al [2011] presented an overview on seismic early warning networks implemented worldwide, along with the development of integrated optimized structural health monitoring (SHM) technologies.…”

Section: Seismic Early Warning and Wireless Control Systemsmentioning

confidence: 99%

Technical Note: Active and Semi-Active Strategies to Control Building Structures Under Large Earthquake Motion

Morales‐Beltran

Paul

2015

Journal of Earthquake Engineering

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Structural Design, Architectural Engineering and Technology, Faculty of Architecture and the Built Environment, TU Delft, Delft, the NetherlandsAs of today, about 80 buildings equipped with active or semi-active devices for wind and earthquake-induced motion control have been reported. In the first part of this technical note, full-scale applications are reviewed to investigate whether large and severe earthquake levels were targeted as control objectives. In the second part, not yet implemented research studies (2011 -2014) are reviewed. The main conclusion is that strategies integrating control and structural design are the key for implementing large earthquake-target control devices in buildings.

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Section: Seismic Early Warning and Wireless Control Systemsmentioning

confidence: 99%

Technical Note: Active and Semi-Active Strategies to Control Building Structures Under Large Earthquake Motion

Morales‐Beltran

Paul

2015

Journal of Earthquake Engineering

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“…Wu et al (2010) present the monitoring of a historic tower in Trento, Italy, which provided valuable information about the structure and its behavior. Rainieri et al (2010) discuss integration of SHM systems with seismic early warning systems (SEWS). This concept is of special interest because the algorithm presented in this paper is potentially applicable to both types of monitoring, which would make the integration of those two systems much easier than with other algorithms.…”

Section: Applications Of Shmmentioning

confidence: 99%

“…This concept is of special interest because the algorithm presented in this paper is potentially applicable to both types of monitoring, which would make the integration of those two systems much easier than with other algorithms. Rainieri et al (2010) further discuss the possibility of using a city-wide system not only for monitoring and forewarning, but also for emergency management after a seismic event. Fabbrocino et al (2009) investigate SHM for retaining walls by means of instrumenting piles.…”

Section: Applications Of Shmmentioning

confidence: 99%

Phase Space Dissimilarity Measures for Structural Health Monitoring

Bubacz¹,

Chmielewski²,

Pape³

et al. 2011

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“…One of the most successful engineering applications of EEW is the Urgent Earthquake Detection and Alarm System (UrEDAS) of the Japan Railway Group [17] for the high-speed Shinkansen trains. Recently, the concept of integrating EEW with SHM in local damage detection [19] or global loss assessment [14] are mentioned by some research groups in Europe. In this paper, our aim is to development a complete synergistic framework between EEW and SHM to optimize the use of the information provided by both systems under a robust Bayesian probabilistic framework.…”

Section: Development Of Eew and Its Applicationsmentioning

confidence: 99%

Synergistic combination of systems for structural health monitoring and earthquake early warning for structural health prognosis and diagnosis

Beck

2012

SPIE Proceedings

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Earthquake early warning (EEW) systems are currently operating nationwide in Japan and are in beta-testing in California. Such a system detects an earthquake initiation using online signals from a seismic sensor network and broadcasts a warning of the predicted location and magnitude a few seconds to a minute or so before an earthquake hits a site. Such a system can be used synergistically with installed structural health monitoring (SHM) systems to enhance pre-event prognosis and post-event diagnosis of structural health. For pre-event prognosis, the EEW system information can be used to make probabilistic predictions of the anticipated damage to a structure using seismic loss estimation methodologies from performance-based earthquake engineering. These predictions can support decision-making regarding the activation of appropriate mitigation systems, such as stopping traffic from entering a bridge that has a predicted high probability of damage. Since the time between warning and arrival of the strong shaking is very short, probabilistic predictions must be rapidly calculated and the decision making automated for the mitigation actions. For post-event diagnosis, the SHM sensor data can be used in Bayesian updating of the probabilistic damage predictions with the EEW predictions as a prior. Appropriate Bayesian methods for SHM have been published. In this paper, we use pre-trained surrogate models (or emulators) based on machine learning methods to make fast damage and loss predictions that are then used in a cost-benefit decision framework for activation of a mitigation measure. A simple illustrative example of an infrastructure application is presented.

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Integrated seismic early warning and structural health monitoring of critical civil infrastructures in seismically prone areas

Cited by 72 publications

References 26 publications

Technical Note: Active and Semi-Active Strategies to Control Building Structures Under Large Earthquake Motion

Technical Note: Active and Semi-Active Strategies to Control Building Structures Under Large Earthquake Motion

Phase Space Dissimilarity Measures for Structural Health Monitoring

Synergistic combination of systems for structural health monitoring and earthquake early warning for structural health prognosis and diagnosis

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