Your search keyword '"earthquake intensity reporting"' showing total 3 results

1. Improved Resolution and Cost Performance of Low-Cost MEMS Seismic Sensor through Parallel Acquisition

Author

Xing-Xing Hu, Xi-Zhen Wang, Bo Chen, Cai-Hua Li, Yi-Xiang Tang, Xiao-Yu Shen, Yuan Zhong, Zhuo-Lin Chen, and Yun-Tian Teng

Subjects

earthquake intensity reporting, earthquake early warning, MEMS accelerometer, correlation average, cost performance, Chemical technology, TP1-1185

Abstract

In earthquake monitoring, an important aspect of the operational effect of earthquake intensity rapid reporting and earthquake early warning networks depends on the density and performance of the deployed seismic sensors. To improve the resolution of seismic sensors as much as possible while keeping costs low, in this article the use of multiple low-cost and low-resolution digital MEMS accelerometers is proposed to increase the resolution through the correlation average method. In addition, a cost-effective MEMS seismic sensor is developed. With ARM and Linux embedded computer technology, this instrument can cyclically store the continuous collected data on a built-in large-capacity SD card for approximately 12 months. With its real-time seismic data processing algorithm, this instrument is able to automatically identify seismic events and calculate ground motion parameters. Moreover, the instrument is easy to install in a variety of ground or building conditions. The results show that the RMS noise of the instrument is reduced from 0.096 cm/s2 with a single MEMS accelerometer to 0.034 cm/s2 in a bandwidth of 0.1–20 Hz by using the correlation average method of eight low-cost MEMS accelerometers. The dynamic range reaches more than 90 dB, the amplitude–frequency response of its input and output within −3 dB is DC −80 Hz, and the linearity is better than 0.47%. In the records from our instrument, earthquakes with magnitudes between M2.2 and M5.1 and distances from the epicenter shorter than 200 km have a relatively high SNR, and are more visible than they were prior to the joint averaging.

Published

2021

2. Improved Resolution and Cost Performance of Low-Cost MEMS Seismic Sensor through Parallel Acquisition

Author

Li Caihua, Zhuo-Lin Chen, Tang Yixiang, Xing-Xing Hu, Yuntian Teng, Bo Chen, Wang Xizhen, Xiaoyu Shen, and Yuan Zhong

Subjects

Microelectromechanical systems, Data processing, correlation average, Warning system, Dynamic range, Computer science, Chemical technology, Acoustics, Bandwidth (signal processing), Linearity, TP1-1185, Accelerometer, Biochemistry, Article, Atomic and Molecular Physics, and Optics, MEMS accelerometer, Analytical Chemistry, earthquake intensity reporting, earthquake early warning, Epicenter, Electrical and Electronic Engineering, cost performance, Instrumentation

Abstract

In earthquake monitoring, an important aspect of the operational effect of earthquake intensity rapid reporting and earthquake early warning networks depends on the density and performance of the deployed seismic sensors. To improve the resolution of seismic sensors as much as possible while keeping costs low, in this article the use of multiple low-cost and low-resolution digital MEMS accelerometers is proposed to increase the resolution through the correlation average method. In addition, a cost-effective MEMS seismic sensor is developed. With ARM and Linux embedded computer technology, this instrument can cyclically store the continuous collected data on a built-in large-capacity SD card for approximately 12 months. With its real-time seismic data processing algorithm, this instrument is able to automatically identify seismic events and calculate ground motion parameters. Moreover, the instrument is easy to install in a variety of ground or building conditions. The results show that the RMS noise of the instrument is reduced from 0.096 cm/s2 with a single MEMS accelerometer to 0.034 cm/s2 in a bandwidth of 0.1–20 Hz by using the correlation average method of eight low-cost MEMS accelerometers. The dynamic range reaches more than 90 dB, the amplitude–frequency response of its input and output within −3 dB is DC −80 Hz, and the linearity is better than 0.47%. In the records from our instrument, earthquakes with magnitudes between M2.2 and M5.1 and distances from the epicenter shorter than 200 km have a relatively high SNR, and are more visible than they were prior to the joint averaging.

Published

2021

3. Improved Resolution and Cost Performance of Low-Cost MEMS Seismic Sensor through Parallel Acquisition.

Author

Hu, Xing-Xing, Wang, Xi-Zhen, Chen, Bo, Li, Cai-Hua, Tang, Yi-Xiang, Shen, Xiao-Yu, Zhong, Yuan, Chen, Zhuo-Lin, and Teng, Yun-Tian

Subjects

*REAL-time computing, *COMPUTER engineering, *EARTHQUAKE magnitude, *EARTHQUAKE intensity, *DETECTORS, *ALGORITHMS

Abstract

In earthquake monitoring, an important aspect of the operational effect of earthquake intensity rapid reporting and earthquake early warning networks depends on the density and performance of the deployed seismic sensors. To improve the resolution of seismic sensors as much as possible while keeping costs low, in this article the use of multiple low-cost and low-resolution digital MEMS accelerometers is proposed to increase the resolution through the correlation average method. In addition, a cost-effective MEMS seismic sensor is developed. With ARM and Linux embedded computer technology, this instrument can cyclically store the continuous collected data on a built-in large-capacity SD card for approximately 12 months. With its real-time seismic data processing algorithm, this instrument is able to automatically identify seismic events and calculate ground motion parameters. Moreover, the instrument is easy to install in a variety of ground or building conditions. The results show that the RMS noise of the instrument is reduced from 0.096 cm/s2 with a single MEMS accelerometer to 0.034 cm/s2 in a bandwidth of 0.1–20 Hz by using the correlation average method of eight low-cost MEMS accelerometers. The dynamic range reaches more than 90 dB, the amplitude–frequency response of its input and output within −3 dB is DC −80 Hz, and the linearity is better than 0.47%. In the records from our instrument, earthquakes with magnitudes between M2.2 and M5.1 and distances from the epicenter shorter than 200 km have a relatively high SNR, and are more visible than they were prior to the joint averaging. [ABSTRACT FROM AUTHOR]

Published

2021