The Urban Seismic Observatory of Catania (Italy): A Real-Time Seismic Monitoring at Urban Scale

Patané, Domenico; Tusa, Giuseppina; Yang, Wenhua; Astuti, Antonio; Colino, Antonio; Costanza, Antonio; D’Anna, Giuseppe; Prima, Sergio Di; Fertitta, Gioacchino; Mangiagli, S.; Martino, Claudio; Torrisi, O.

doi:10.3390/rs14112583

Cited by 8 publications

(1 citation statement)

References 48 publications

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“…Patanè et al investigated low-noise and ultra-low-noise MEMS accelerometers with the ultra-low noise M−A352 Q−MEMS accelerometer in situ on the ground floor of a historic and strategic building in the city center. A series of tests have in fact shown that such a cost-effective accelerometer could play a key role in monitoring low-level seismicity and could be used in urban observatories and for SHM [ 25 ]. In this paper, smaller 3-axis low-cost and low-noise MEMS accelerometers were used to obtain the vibration data of the Great Wall.…”

Section: Introductionmentioning

confidence: 99%

The Great Wall Vibration Monitoring of Traffic and Natural Hazards Using MEMS Accelerometers

Wang

Liu

et al. 2023

Sensors

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The stability of the Great Wall is mainly affected by traffic vibrations and natural hazards, such as strong winds, heavy rainfall, and thunderstorms, which are extremely harmful to the safety of the Great Wall. To determine the impact of the above factors on the Great Wall, a comparative analysis based on MEMS (micro-electro-mechanical system) accelerometer data was conducted between the non-impacts and the impacts of the above factors. An analysis of the relationship between vibration acceleration and each potential hazard based on a visual time series chart was presented using the data of accelerometers, traffic video, meteorology, rainfall, and wind. According to the results, traffic vibration is one of the primary dangerous factors affecting the stability of the Great Wall, Moreover, the intensity of the vibrations increases with the traffic flow. Thunderstorms also influence the stability of the Great Wall, with enhanced thunderstorm excitation resulting in increased vibration displacement. Furthermore, wind load is an influencing factor, with average wind speeds greater than 9 m/s significantly affecting the stability of the Great Wall. Rainfall has no impact on the stability of the Great Wall in the short term. This research can provide important guidance for risk assessment and protection of the Great Wall.

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Section: Introductionmentioning

confidence: 99%