<p>In the face of increasing security requirements, threat identification requires technology with uncompromising sensitivity and responsiveness. This article presents a sensor with enhanced sensitivity, designed to detect rotational ground movement. Its physical basis on the Sagnac effect provides an absolute measurement of rotation. From a geotechnical and engineering perspective, the configuration of several such sensors enables precise determination of the epicentral coordinates of seismic events and identification of local material degradation zones, where differences in signal transit time and amplitude between individual network nodes provide the basis for mapping discontinuities in the studied medium. The primary goal of the presented research was to verify the feasibility of creating an integrated sensor array capable of precisely monitoring a defined area. Using highly correlated sensors with time synchronization of the order of 10 ns we obtained signals from artificial disturbances. The time-of-arrival analysis of recorded sensor signals successfully demonstrated the ability to quickly determine the locations of explosions. The presented solution offers new perspectives for early warning systems, providing not only threat detection but also accurate spatial positioning of threats using highly sensitive rotational sensors.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

High spatial resolution of the rotational sensor array in the explosion sources localization

  • Anna T. Kurzych,
  • Leszek R. Jaroszewicz,
  • Grzegorz Lizurek,
  • Bartosz Sakowicz,
  • Michał Dudek,
  • Karol Konarski,
  • Paweł Zinówko

摘要

In the face of increasing security requirements, threat identification requires technology with uncompromising sensitivity and responsiveness. This article presents a sensor with enhanced sensitivity, designed to detect rotational ground movement. Its physical basis on the Sagnac effect provides an absolute measurement of rotation. From a geotechnical and engineering perspective, the configuration of several such sensors enables precise determination of the epicentral coordinates of seismic events and identification of local material degradation zones, where differences in signal transit time and amplitude between individual network nodes provide the basis for mapping discontinuities in the studied medium. The primary goal of the presented research was to verify the feasibility of creating an integrated sensor array capable of precisely monitoring a defined area. Using highly correlated sensors with time synchronization of the order of 10 ns we obtained signals from artificial disturbances. The time-of-arrival analysis of recorded sensor signals successfully demonstrated the ability to quickly determine the locations of explosions. The presented solution offers new perspectives for early warning systems, providing not only threat detection but also accurate spatial positioning of threats using highly sensitive rotational sensors.