Michal Chamarczuk, Jonathan B. Ajo‐Franklin, A. Nayak, Verónica Rodríguez Tribaldos
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引用次数: 0
Abstract
Distributed acoustic sensing (DAS), deployed on dark telecom fiber, is well-positioned to play a significant role in seismic monitoring networks because of the combination of a large aperture, fine spatial resolution, broadband sensitivity, and the ubiquitous presence of unused telecommunication fibers in many areas of the world. In this study, we explore the feasibility of dark-fiber array deployed in a noisy environment for detecting small explosions. We test the effectiveness of template matching for the detection of low-frequency blasts generated by mining activities in the Imperial Valley, California. We first evaluate dark-fiber detection performance by analyzing the relationship between detection threshold (DT) and the number of DAS channels used. We find that although, as expected, increasing the number of channels yields higher detection significance and lowers DT, the gain in performance is far from linear, with local anomalies across the DAS cable associated with zones of higher noise. We focus on investigating the types of noise affecting template matching and practical approaches mitigating anthropogenic noise that lower detection performance. Using median absolute deviation, we identify two types of noise sources affecting detection performance. Next, we design a voting scheme that selects DAS channels contributing to lowering of the DT and ensures improvement in detection when adding sequential channels. Finally, we compare dark-fiber detection performance with nearby conventional seismometers and find that a single station can outperform up to ∼10 DAS channels. However, using the full aperture of our dark-fiber transect allows to obtain ∼10% lower DT and yields fewer false-positive detections than an array of four seismometers. Methodological solutions for noise assessment and channel selection allow us to fully benefit from the large aperture and dense sampling offered by dark fiber. The findings of this study are a step toward incorporating existing telecom fibers into novel explosion-monitoring workflows.
部署在暗电信光纤上的分布式声学传感(DAS)具有孔径大、空间分辨率高、宽带灵敏度高的特点,而且世界上许多地区都存在闲置的电信光纤,因此完全有条件在地震监测网络中发挥重要作用。在本研究中,我们探讨了在嘈杂环境中部署暗光纤阵列探测小型爆炸的可行性。我们测试了模板匹配在检测加利福尼亚帝国谷采矿活动产生的低频爆炸方面的有效性。我们首先通过分析检测阈值(DT)与所使用的 DAS 信道数量之间的关系来评估暗光纤检测性能。我们发现,虽然正如预期的那样,增加信道数可以提高检测精度并降低 DT,但性能的提高远非线性的,整个 DAS 电缆的局部异常与噪声较高的区域有关。我们重点研究了影响模板匹配的噪声类型,以及降低检测性能的人为噪声的实用方法。利用绝对偏差中值,我们确定了影响检测性能的两类噪声源。接下来,我们设计了一种投票方案,可选择有助于降低 DT 的 DAS 信道,并确保在添加连续信道时提高检测性能。最后,我们将暗光纤探测性能与附近的传统地震仪进行了比较,发现单个台站的性能最多可超过 10 个 DAS 频道。然而,与四个地震仪阵列相比,使用暗光纤横断面的全孔径可使 DT 值降低 10%,假阳性检波也更少。噪声评估和信道选择的方法解决方案使我们能够充分受益于暗光纤提供的大孔径和密集采样。这项研究的结果为将现有电信光纤纳入新型爆炸监测工作流程迈出了一步。