Optimal Network Design for Microseismic Monitoring in Urban Areas - A Case Study in Munich, Germany

Seismica Pub Date : 2023-10-18 DOI:10.26443/seismica.v2i2.1030

Sabrina Keil, Joachim Wassermann, Tobias Megies, Toni Kraft

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Abstract

Well-designed monitoring networks are crucial for obtaining precise locations, magnitudes and source parameters, both for natural and induced microearthqakes. The performance of a seismic network depends on many factors, including network geometry, signal-to-noise ratio (SNR) at the seismic station, instrumentation and sampling rate. Therefore, designing a high-quality monitoring network in an urban environment is challenging due to the high level of anthropogenic noise and dense building infrastructure, which can impose geometrical limitations and elevated construction costs for sensor siting. To address these challenges, we apply a numerical optimization approach to design a microseismic surveillance network for induced earthquakes in the metropolitan area of Munich (Germany), where several geothermal plants exploit a deep hydrothermal reservoir. First of all, we develop a detailed noise model for the city of Munich, to capture the heterogeneous noise conditions. Then, we calculate the expected location precision for a randomly chosen network geometry from the body-wave amplitudes and travel times of a synthetic earthquake catalog considering the modeled local noise level at each network station. In the next step, to find the optimum network configuration, we use a simulated annealing approach in order to minimize the error ellipsoid volume of the linearized earthquake location problem. The results indicate that a surface station network cannot reach the required location precision (0.5 km in epicentre and 2 km in source depth) and detection capability (magnitude of completeness Mc = 1.0) due to the city´s high seismic noise level. In order to reach this goal, borehole stations need to be added to increase the SNR of the microearthquake recordings, the accuracy of their body-wave arrival times and source parameters. The findings help to better quantify the seismic monitoring requirements for a save operation of deep geothermal projects in urban areas.

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城市微震监测网络优化设计——以德国慕尼黑为例

设计良好的监测网络对于获取自然和诱发微地震的精确位置、震级和震源参数至关重要。地震台网的性能取决于许多因素，包括网络几何形状、地震台站的信噪比(SNR)、仪器和采样率。因此，由于高水平的人为噪声和密集的建筑基础设施，在城市环境中设计一个高质量的监测网络是具有挑战性的，这可能会给传感器选址带来几何限制和更高的建设成本。为了解决这些挑战，我们应用数值优化方法在慕尼黑(德国)的大都市地区设计了一个诱发地震的微地震监测网，那里有几个地热发电厂开发了一个深热液储层。首先，我们为慕尼黑市建立了一个详细的噪声模型，以捕捉异质性噪声条件。然后，考虑每个台站模拟的局部噪声水平，我们从合成地震目录的体波振幅和传播时间计算随机选择的网络几何形状的期望定位精度。在下一步，为了找到最优的网络配置，我们使用模拟退火方法来最小化线性化地震定位问题的误差椭球体积。结果表明，由于城市的高地震噪声水平，地面台站网络无法达到所需的定位精度(震中0.5 km，震源深度2 km)和检测能力(完整性等级Mc = 1.0)。为了达到这一目标，需要增加钻孔台站，以提高微震记录的信噪比、体波到达时间和震源参数的精度。研究结果有助于更好地量化城市地区深层地热项目节约运营的地震监测需求。

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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Seismica

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