Design and Implementation of a High Precision Time Synchronization Method for Borehole-surface Microseismic Monitoring

Q4 Engineering

International Journal of Circuits, Systems and Signal Processing Pub Date : 2022-03-10 DOI:10.46300/9106.2022.16.98

Yadongyang Zhu, Wen-peng Wei

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Abstract

Borehole-surface monitoring can effectively improve the accuracy of the microseismic event location. It is necessary to strictly synchronize the acquisition time of borehole and surface monitoring nodes. However, the synchronization signal transmission through the logging cable will cause a delay. In this paper, a calibration method designed to compensate for the deviation of time synchronization due to long-distance transmission on the logging cable. First, the transmission delay of the pulse per second (PPS) is measured in the delay measurement stage. The delay from the global positioning system (GPS) module to all monitoring nodes can get in sequence. Second, In the delay compensation stage, each monitoring node is delayed for a particular time to ensure that all nodes start working simultaneously. Finally, a high-precision clock source is designed to drive the analog-to-digital converter (ADC) to avoid the crystal oscillator’s accumulated error. To verify the accuracy of the calibration method, the modules were tested separately. The length of the logging cable used is 3000 meters. Through experimental verification, the method in this paper can be used to accurately control the time synchronization of different monitoring nodes in the borehole and on the surface within 1us.

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井-地微震监测高精度时间同步方法的设计与实现

井地监测可以有效地提高微震事件定位的精度。必须严格同步井内和地面监测节点的采集时间。但是，通过测井电缆传输同步信号会产生延时。本文设计了一种校正方法来补偿由于测井电缆上的远距离传输造成的时间同步偏差。首先，在延迟测量阶段测量脉冲每秒(PPS)的传输延迟。从全球定位系统(GPS)模块到各监控节点的时延可以按顺序得到。在延迟补偿阶段，对每个监控节点进行一定的延迟，保证所有节点同时开始工作。最后，设计了高精度时钟源驱动模数转换器(ADC)，避免了晶体振荡器的累积误差。为了验证标定方法的准确性，对各模块分别进行了测试。使用的测井电缆长度为3000米。通过实验验证，本文方法可以在1us内精确控制井内和地表不同监测节点的时间同步。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Circuits, Systems and Signal Processing Engineering-Electrical and Electronic Engineering

自引率

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发文量

155