Jiangnan Lin, Wenbin Jiang, Yong Zhou, Bin Liu, Minghui Zhao, Zhuo Xiao, Lingmin Cao, Min Xu
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Our analysis revealed substantial correlations between crowd motions during different phases of the event and ambient noise features recorded by DAS. Moreover, the cross-correlation functions of the ambient noise with its dispersion characteristics pointed to near-field pedestrian activity as the primary noise source. Real-time heat maps of human crowd motions were reconstructed from DAS recording, offering significant insights into the variations of activity intensity across different locations. Discerning fireworks events on the DAS array is more effective than on a scattered seismometer array, because it is easier to ensure that the same event is picked for all the sites in the DAS dense linear configuration. The DAS data inspection allowed us to pick up a total of 549 firecracker explosions in comparison to the seismometer data that only allowed us to detect 116 firecracker events. The heights of fireworks were located by the grid-search method and predominantly distributed at 75–300 m, closely aligning with actual fireworks explosion locations. Our findings underscore that the DAS technology can monitor crowd motion and detect vibration signals in the air, bridging the gap between fundamental earth science research and human social activities.","PeriodicalId":2,"journal":{"name":"ACS Applied Bio Materials","volume":null,"pages":null},"PeriodicalIF":4.6000,"publicationDate":"2024-02-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Distributed Acoustic Sensing for Crowd Motion and Firecracker Explosions in the Fireworks Show\",\"authors\":\"Jiangnan Lin, Wenbin Jiang, Yong Zhou, Bin Liu, Minghui Zhao, Zhuo Xiao, Lingmin Cao, Min Xu\",\"doi\":\"10.1785/0220230346\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"\\n Urban seismology has recently emerged as a vibrant scientific field, driven by the growing interest in seismic signals generated by major public events, sports gatherings, and transportation services. 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引用次数: 0
摘要
最近,随着人们对重大公共活动、体育集会和交通服务产生的地震信号的兴趣日益浓厚,城市地震学已成为一个充满活力的科学领域。然而,在经济活跃、人口稠密、交通繁忙的城市地区部署密集的传统地震仪是一项重大挑战。在本研究中,我们利用分布式声学传感(DAS)技术在 2023 年 2 月 5 日广州烟花汇演期间进行了现场实验。约 572 米长的光纤被改造成 286 个地震传感器,部署在灵山岛上,用于监测烟花表演期间产生的各种振动信号。我们的分析表明,活动不同阶段的人群运动与 DAS 记录的环境噪声特征之间存在很大的相关性。此外,环境噪声与其扩散特征的交叉相关函数表明,近场行人活动是主要的噪声源。通过 DAS 记录重建了人群运动的实时热图,为了解不同地点的活动强度变化提供了重要依据。在 DAS 阵列上分辨烟花事件比在散布式地震仪阵列上分辨烟花事件更有效,因为在 DAS 密集线性配置中,更容易确保在所有地点选取相同的事件。通过 DAS 数据检查,我们总共发现了 549 次爆竹爆炸事件,而地震仪数据只能发现 116 次爆竹事件。烟花的高度是通过网格搜索法确定的,主要分布在 75-300 米处,与实际烟花爆炸位置非常吻合。我们的研究结果表明,DAS 技术可以监测人群运动并探测空气中的振动信号,在地球科学基础研究与人类社会活动之间架起了一座桥梁。
Distributed Acoustic Sensing for Crowd Motion and Firecracker Explosions in the Fireworks Show
Urban seismology has recently emerged as a vibrant scientific field, driven by the growing interest in seismic signals generated by major public events, sports gatherings, and transportation services. However, deploying dense traditional seismometers in economically active, densely populated urban areas with heavy traffic poses significant challenges. In this study, we conducted a field experiment utilizing distributed acoustic sensing (DAS) technology during a fireworks display in Guangzhou on 5 February 2023. About 572 m of optical fiber was turned into 286 seismic sensors and deployed on LingShan Island to monitor various vibration signals generated during the fireworks show. Our analysis revealed substantial correlations between crowd motions during different phases of the event and ambient noise features recorded by DAS. Moreover, the cross-correlation functions of the ambient noise with its dispersion characteristics pointed to near-field pedestrian activity as the primary noise source. Real-time heat maps of human crowd motions were reconstructed from DAS recording, offering significant insights into the variations of activity intensity across different locations. Discerning fireworks events on the DAS array is more effective than on a scattered seismometer array, because it is easier to ensure that the same event is picked for all the sites in the DAS dense linear configuration. The DAS data inspection allowed us to pick up a total of 549 firecracker explosions in comparison to the seismometer data that only allowed us to detect 116 firecracker events. The heights of fireworks were located by the grid-search method and predominantly distributed at 75–300 m, closely aligning with actual fireworks explosion locations. Our findings underscore that the DAS technology can monitor crowd motion and detect vibration signals in the air, bridging the gap between fundamental earth science research and human social activities.