Toward Structural Health Monitoring with the MyShake Smartphone Network

Patel, Sarina C.; Günay, Selim; Marcou, Savvas; Gou, Yuancong; Kumar, Utpal; Allen, Richard M.

doi:10.3390/s23218668

Cited by 2 publications

(1 citation statement)

References 39 publications

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“…Many techniques have been developed to obtain information about structural health by examining the vibration responses of a structure [6][7][8][9][10]. In such techniques, the response of the building to forced or free vibrations by means of accelerometers placed at certain points of the building is tested to obtain information about the structural health by using different algorithms [10][11][12]. We can categorize vibration-based structural health monitoring methods into parametric and non-parametric approaches.…”

Section: Literature Reviewmentioning

confidence: 99%

Damage Classification of a Three-Story Aluminum Building Model by Convolutional Neural Networks and the Effect of Scarce Accelerometers

Ercan,

Avcı,

Pekedis

et al. 2024

Applied Sciences

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Structural health monitoring (SHM) plays a crucial role in extending the service life of engineering structures. Effective monitoring not only provides insights into the health and functionality of a structure but also serves as an early warning system for potential damages and their propagation. Structural damages may arise from various factors, including natural phenomena and human activities. To address this, diverse applications have been developed to enable timely detection of such damages. Among these, vibration-based methods have received considerable attention in recent years. By leveraging advancements in computer processing capabilities, machine learning and deep learning algorithms have emerged as promising tools for enhancing the efficiency and accuracy of vibration-based SHM. This study focuses on the application of convolutional neural networks (CNNs) for the classification and detection of structural damage within a steel-aluminum building model. An experimental platform was devised and constructed to generate data representative of building damage scenarios induced by bolt loosening. Both the typical placement of sensors on each floor and the utilization of only one accelerometer were employed to understand the effect of scarcity of accelerometers. By subjecting the building model to controlled vibrations and environmental conditions, the response data from both sensor configurations were collected and analyzed to evaluate the effectiveness of the CNN approach in detecting structural damage under varying sensor deployment strategies. The findings demonstrate that the CNNs exhibited high accuracy in both damage classification and detection, even under scenarios with limited sensor coverage. Moreover, the proposed method proved effective in identifying structural damage within building structures.

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Section: Literature Reviewmentioning

confidence: 99%

Damage Classification of a Three-Story Aluminum Building Model by Convolutional Neural Networks and the Effect of Scarce Accelerometers

Ercan,

Avcı,

Pekedis

et al. 2024

Applied Sciences

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Ground-Motion Modeling Using MyShake Smartphone Peak Acceleration Data

Marcou,

Allen,

Abrahamson

et al. 2024

Bulletin of the Seismological Society of America

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In the field of ground-motion modeling, the availability of densely sampled ground-motion data is becoming key to mapping repeatable source, path, and site effects to enable ground-motion models (GMMs) to more accurately predict shaking from future earthquakes. This is particularly important because the field is moving toward nonergodic GMMs with spatially variable coefficients. To achieve the level of sampling required, the addition of non-instrumental data collected at very high spatial resolution, like felt intensity data or smartphone data, could prove essential. The predictive power of this nontraditional data for free-field ground motion needs to be tested before these data are used. In this work, we present a new database of over 1600 ground-shaking waveforms collected between 2019 and 2023 by the MyShake smartphone app, which delivers earthquake early warning messages to users on the U.S. West Coast. We develop a GMM, MyShake GMM, for peak smartphone-recorded accelerations in 3≤M≤5.5 earthquakes recorded at short (<50 km) distances. We compare our model with free-field GMMs and show a similar geometric decay and a close match in predicted amplitudes for short-period spectral accelerations (SAs). We use residual correlation analysis to show that MyShake GMM residuals have a positive correlation with free-field residuals, with correlation coefficients of around 0.4 for peak ground acceleration, velocity, and short-period SA, similar to correlations previously reported between felt intensity and free-field data. This illustrates the potential that densely sampled smartphone ground-shaking data has in identifying repeatable free-field ground-motion effects for various ground-motion modeling applications. These could potentially include highly location-specific assessments of site response, ground-motion interpolation schemes like ShakeMap, or validating outputs from nonergodic, spatially variable coefficient GMMs.

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Toward Structural Health Monitoring with the MyShake Smartphone Network

Cited by 2 publications

References 39 publications

Damage Classification of a Three-Story Aluminum Building Model by Convolutional Neural Networks and the Effect of Scarce Accelerometers

Damage Classification of a Three-Story Aluminum Building Model by Convolutional Neural Networks and the Effect of Scarce Accelerometers

Ground-Motion Modeling Using MyShake Smartphone Peak Acceleration Data

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