利用分布式光纤声波传感器监测大容量气枪震源信号

doi:10.3969/j.issn.0253-4967.2020.05.015

地震地质 ›› 2020, Vol. 42 ›› Issue (5): 1255-1265.DOI: 10.3969/j.issn.0253-4967.2020.05.015

• 新技术应用 • 上一篇

利用分布式光纤声波传感器监测大容量气枪震源信号

李孝宾¹⁾, 宋政宏^2,3), 杨军¹⁾, 曾祥方^2),*, 王宝善³⁾

1)云南省地震局, 昆明 650224;
2)中国科学院精密测量科学与技术创新研究院, 大地测量与地球动力学国家重点实验室, 武汉 430077;
3)中国科学技术大学地球和空间科学学院, 合肥 230026

收稿日期:2019-11-26 修回日期:2020-08-04 出版日期:2020-10-20 发布日期:2021-01-06
通讯作者: *曾祥方, 男, 1984年生, 研究员, 现主要研究方向为地震震源、结构成像和光纤传感技术应用研究, E-mail:zengxf@apm.ac.cn。
作者简介:李孝宾, 男, 1982年生, 2005年于云南财贸学院获信息与计算科学专业学士学位, 工程师, 现主要研究方向为主动震源和地震流动观测, 电话: 13324959432, E-mail: codepanda@qq.com。
基金资助:
国家自然科学基金(41974067, 41790462, 41574059)和云南省陈颙院士工作站(2014IC007)共同资助

MONITORING SIGNAL OF AIRGUN SOURCE WITH DISTRIBUTED ACOUSTIC SENSING

LI Xiao-bin¹⁾, SONG Zheng-hong^2,3), YANG Jun¹⁾, ZENG Xiang-fang²⁾, WANG Bao-shan³⁾

1)Yunnan Earthquake Agency, Dali, Yunnan 650224, China;
2)State Key Laboratory of Geodesy and Earth's Dynamics, Innovation Academy of Precision Measurement Science and Technology, CAS, Wuhan 430077, China;
3)School of Earth and Space Sciences, University of Science and Technology of China, Hefei 230026, China

Received:2019-11-26 Revised:2020-08-04 Online:2020-10-20 Published:2021-01-06

摘要/Abstract

摘要： 近年来出现的新型高密度地震观测系统——分布式光纤声波传感器(Distributed Acoustic Sensing, DAS)有望提高地震成像的空间分辨率。为探索该技术在监测介质动态变化方面的应用, 在云南省宾川县布设了长约180m的传感光缆, 对9.6km外的宾川大容量气枪震源的激发信号进行了监测。在为期2d的实验期间, 对气枪震源进行了24次高重复激发, 采用时频域加权相位叠加算法对多炮和多道记录进行叠加处理, 得到了高质量的地震波信号, 与共址观测的地震仪记录具有较高的一致性。通过此次观测实验, 初步验证了利用DAS监测大容量气枪震源信号的可行性, 未来有望将其推广应用于高分辨率4D地震成像研究中。

关键词: 大容量气枪, 分布式光纤声波传感, 台阵技术

Abstract: The large-volume airgun system was introduced to excite highly repetitive seismic signal for medium change monitoring. Using dense seismic array to record the seismic wavefield will be helpful to high spatial resolution time-lapse tomography. However, most dense arrays employ the nodal short-period geophone with built-in battery that is not suitable for permanent monitoring. The novel distributed acoustic sensing(DAS)technology uses fiber-optic itself as sensor that providing small station spacing. The incident seismic wavefiled induces tiny strain of the fiber-optic that leads to phase change of the Rayleigh backscattered optical signal. Therefore, measuring the phase difference between two signals scattered at two nearby scatterers can be used to recover seismic signal. Since the scatter is randomly distributed in the fiber-optic, it is possible to record seismic wavefield with spacing down to sub-meters. Each optical signal is processed in the interrogator. Therefore, the DAS array is easily maintained as a permanent dense array for seismic monitoring. We conducted a pilot experiment to test feasibility of using DAS array to record airgun signal in Binchuan, Yunnan Province.
The Binchuan Fixed Airgun Signal Transmission Station built in 2011 is the first inland large-volume airgun in China. The airgun system consists of four Bolt LL 1500 airguns and fires at 10m depth in a reservoir. The seismic energy released by one airgun shot is close to the one of M_L0.7 earthquake. During this pilot experiment, the airgun was continuously shot after midnight with an interval of 15 minute. The DAS array is a micro-structured fiber-optic buried in an “L-shape” trench, which is about 9.8km away from the airgun. To enhance SNR of the optical signal used for recover seismic signal, a series of ultra-weak fiber Bragg gratings were built in the fiber with 2m spacing. The 180m fiber-optic is buried at about 20cm depth and the trench is backfilled with sand. The channel spacing is 4m and the interrogator continuously records at 1 000Hz.
The signal is barely visible on the record of single shot due to strong ambient seismic noise and optical noise. Since the seismic signal excited by the airgun is highly repetitive, we used the time-frequency phase weighted stacking method to stack records of multiple shots. The signals clearly emerge on the stack traces and the arrival time agrees well with the records of a co-located seismometer. Compared with the seismometer's record, the DAS records concentrate in a higher frequency band(5~8Hz). Since the DAS and seismometer record the seismic wavefield in dynamic strain and particle velocity, respectively, the frequency-wavenumber scaling algorithm was used to convert DAS's strain record to particle velocity record that shows clear phase difference from seismometer's record. The difference between records of DAS and seismometer was analyzed in time-frequency domain. The largest difference occurs between 3 and 6Hz in the airgun signal wave train, which may due to lower sensitivity in lower frequency band of DAS.
The bootstrapping resample method was used to evaluate the stacking converge rate of two datasets. Comparing to the reference trace that is stacked with 24 shots, the cross-correlation coefficient reaches 0.9 with only four shots for the seismometer dataset. At the meantime, the cross-correlation coefficient is only 0.8 with 20 shots for the DAS dataset. To improve the stacking efficiency, we also tried the array stacking method. The records of 26 channels on the X lag of the array were stacked. The one-shot stacking suppressed the traffic noise from a nearby street and the airgun signal clearly emerges on the one-shot stacking trace. The airgun signals on the stacking traces of multiple shots and multiple channels are comparable, which suggest the multiple channels stacking can be used to improve time resolution for time-lapse tomography/monitoring.
In summary, the airgun signal is successfully recorded by a DAS array with an engineered fiber-optic cable. Comparing with the seismometer, DAS dataset is strongly affected by the traffic noise and lower sensitive to lower frequency band. The dense spacing also provides opportunity to stack multiple channels’ records that improves SNR of airgun signal. Since the lack of reliable vertical component records, the phase identification cannot be done via particle motion analysis. The aperture of our DAS array is too small to estimate the apparent velocity to identify seismic phase too. In the future, it is worth to use telecom fiber-optic cables as sensor for time-lapse tomography, which have been widely deployed in urban area and significantly reduced deployment cost.
The clear variation of waveforms across one lag arising from un-uniform coupling was also observed. To comprehensively evaluate the monitor capability, it is important to deploy large aperture DAS array for seismic signal attenuation analysis. Our result suggests that the stronger lower frequency system noise of the DAS integrator reduces the sensitivity to seismic signal. More attention should be paid to approaches such as environmental vibration isolation and optical noise reduction. Another issue is accurate response function. Calibration with co-located seismometers and numerical modeling are helpful to provide accurate sensitivity and response function, which is important in seismology studies.

Key words: airgun, distributed acoustic sensing, array processing

中图分类号:

P315.61

李孝宾, 宋政宏, 杨军, 曾祥方, 王宝善. 利用分布式光纤声波传感器监测大容量气枪震源信号[J]. 地震地质, 2020, 42(5): 1255-1265.

LI Xiao-bin, SONG Zheng-hong, YANG Jun, ZENG Xiang-fang, WANG Bao-shan. MONITORING SIGNAL OF AIRGUN SOURCE WITH DISTRIBUTED ACOUSTIC SENSING[J]. SEISMOLOGY AND GEOLOGY, 2020, 42(5): 1255-1265.

参考文献

[1] 陈颙, 王宝善, 葛洪魁, 等. 2007a. 建立地震发射台的建议[J]. 地球科学进展, 22(5): 441—446.
CHEN Yong, WANG Bao-shan, GE Hong-kui, et al. 2007a. Proposed of transmitted seismic stations[J]. Advances in Earth Science, 22(5): 441—446(in Chinese).
[2] 陈颙, 王宝善, 姚华建. 2017. 大陆地壳结构的气枪震源探测及其应用[J]. 中国科学:(D辑), 47(10): 1153—1165.
CHEN Yong, WANG Bao-shan, YAO Hua-jian.2017. Seismic airgun exploration of continental crust structures[J]. Science in China(Ser D), 47(10): 1153—1165(in Chinese).
[3] 陈颙, 张先康, 丘学林, 等. 2007b. 陆地人工激发地震波的一种新方法[J]. 科学通报, 52(11): 1317—1321.
CHEN Yong, ZHANG Xian-kang, QIU Xue-lin, et al. 2007b. A new method of artificially excited seismic waves on land[J]. Chinese Science Bulletin, 52(11): 1317—1321(in Chinese).
[4] 林融冰, 曾祥方, 宋政宏, 等. 2020. 分布式光纤声波传感系统在近地表成像中的应用Ⅱ: 背景噪声成像[J]. 地球物理学报, 63(4): 1622—1629. doi: 10.6038/cjg2020N0272.
LIN Rong-bing, ZENG Xiang-fang, SONG Zheng-hong, et al. 2020. Distributed acoustic sensing for imaging shallow structure Ⅱ: Ambient noise tomography[J]. Chinese Journal of Geophysics, 63(4): 1622—1629(in Chinese).
[5] 宋政宏, 曾祥方, 徐善辉, 等. 2020. 分布式光纤声波传感系统在近地表成像中的应用I: 主动源高频面波[J]. 地球物理学报, 63(2): 532—540. doi: 10.6038/cjg2020N0184.
SONG Zheng-hong, ZENG Xiang-fang, XU Shan-hui, et al. 2020. Distributed acoustic sensing for imaging shallow structure I: Active source survey[J]. Chinese Journal of Geophysics, 63(2): 532—540(in Chinese).
[6] 王宝善, 葛洪魁, 王彬, 等. 2016. 利用人工重复震源进行地下介质结构及其变化研究的探索和进展[J]. 中国地震, 32(2): 168—179.
WANG Bao-shan, GE Hong-kui, WANG Bin, et al. 2016. Practices and advances in exploring the subsurface structure and its temporal evolution with repeatable artificial sources[J]. Earthquake Research in China, 32(2): 168—179(in Chinese).
[7] 王彬, 吴国华, 苏有锦, 等. 2015. 宾川地震信号发射台的选址、建设及初步观测结果[J]. 地震研究, 38(1): 1—6.
WANG Bin, WU Guo-hua, SU You-jin, et al. 2015. Site selection and construction process of Binchuan earthquake signal transmitting seismic station and its preliminary observation result[J]. Journal of Seismological Research, 38(1): 1—6(in Chinese).
[8] 武安绪, 叶泵, 李红, 等. 2016. 气枪震源弱信号提取的可靠性初步分析[J]. 中国地震, 32(2): 319—330.
WU An-xu, YE Beng, LI Hong, et al. 2016. The preliminary analysis of reliability on weak signal extraction for air-gun source surveys[J]. Earthquake Research in China, 32(2): 319—330(in Chinese).
[9] 杨微, 王宝善, 葛洪魁, 等. 2013. 大容量气枪震源主动探测技术系统及试验研究[J]. 中国地震, 29(4): 399—410.
YANG Wei, WANG Bao-shan, GE Hong-kui, et al. 2013. The active monitoring system with large volume airgun source and experiment[J]. Earthquake Research in China, 29(4): 399—410(in Chinese).
[10] 张丽娜, 任亚玲, 林融冰, 等. 2020. 分布式光纤声波传感器及其在天然地震学研究中的应用[J]. 地球物理学进展, 35(1): 65—71. doi: 10.6038/pg2020DD0384.
ZHANG Li-na, REN Ya-ling, LIN Rong-bing, et al. 2020. Distributed acoustic sensing system and its application for seismological studies[J]. Progress in Geophysics, 35(1): 65—71(in Chinese).
[11] Ben-Zion Y, Vernon F L, Ozakin Y, et al. 2015. Basic data features and results from a spatially dense seismic array on the San Jacinto fault zone[J]. Geophysical Journal International, 202(1): 370—380.
[12] Jousset P, Reinsch T, Ryberg T, et al. 2018. Dynamic strain determination using fibre-optic cables allows imaging of seismological and structural features[J]. Nature Communications, 9(1): 1—11.
[13] Kiser E, Levander A, Zelt C, et al. 2019. Upper crustal structure and magmatism in southwest Washington: V_P, V_S, and V_P/V_S results from the iMUSH active-source seismic experiment[J]. Journal of Geophysical Research: Solid Earth, 124(7): 7067—7080.
[14] Kristekova M, Kristek J, Moczo P.2009. Time-frequency misfit and goodness-of-fit criteria for quantitative comparison of time signals[J]. Geophysical Journal International, 178(2): 813—825.
[15] Lin F C, Li D, Clayton R W, et al. 2013. High-resolution 3D shallow crustal structure in Long Beach, California: Application of ambient noise tomography on a dense seismic array[J]. Geophysics, 78(4): 45—56.
[16] Lindsey N J, Martin E R, Dreger D S, et al. 2017. Fiber-optic network observations of earthquake wavefields[J]. Geophysical Research Letters, 44(23): 11792—11799.
[17] Parker T, Shatalin S, Farhadiroushan M.2014. Distributed acoustic sensing: A new tool for seismic applications[J]. First Break, 32(2): 61—69.
[18] Rost S, Thomas C.2002. Array seismology: Methods and applications[J]. Reviews of geophysics, 40(3): 2-1—2—27.
[19] Schimmel M, Stutzmann E, Gallart J.2011. Using instantaneous phase coherence for signal extraction from ambient noise data at a local to a global scale[J]. Geophysical Journal International, 184(1): 494—506.
[20] Song Z H, Zeng X F, Thurber C, et al. 2018. Imaging shallow structure with active-source surface wave signal recorded by distributed acoustic sensing arrays[J]. Earthquake Science, 31:208—214.
[21] Su J B, Wang Q, Zhang W X, et al. 2019. The seasonal variation of large volume airgun signals in Hutubi, Xinjiang[J]. Earthquake Research in China, 33(2): 186—194.
[22] Wang B, Ge H, Yang W, et al. 2012. Transmitting seismic station monitors fault zone at depth[J]. Eos, Transactions American Geophysical Union, 93(5): 49—50.
[23] Wang B, Tian X, Zhang Y, et al. 2018. Seismic signature of an untuned large-volume airgun array fired in a water reservoir[J]. Seismological Research Letters, 89(3): 983—991.
[24] Wang B, Yang W, Wang W, et al. 2020. Diurnal and semidiurnal P-and S-wave velocity changes measured using an airgun source[J]. Journal of Geophysical Research: Solid Earth, 125(1): e2019JB018218.
[25] Wang H F, Zeng X, Miller D E, et al. 2018. Ground motion response to an M_L4.3 earthquake using co-located distributed acoustic sensing and seismometer arrays[J]. Geophysical Journal International, 213(3): 2020—2036.
[26] Wang W, Zhou Q, Kou H, et al. 2019. Improving airgun signal detection with small-aperture seismic array in Yunnan[J]. Earthquake Research in China, 33(2): 248—264.
[27] Xiang Y, Yang R H, Wang B, et al. 2019. Study on the influence of airgun excitation conditions on airgun signals and travel time variation measurements[J]. Earthquake Research in China, 33(2): 336—353.
[28] Xu Y, Wang B, Wang W, et al. 2018. Multiple seismological evidences of basin effects revealed by array of Binchuan(ABC), northwest Yunnan, China[J]. Earthquake Science, 31(5-6): 281—290.
[29] Yao H, Wang B, Tian X, et al. 2018. Preface to the special issue of dense array seismology[J]. Earthquake Science, 31:225—226.

利用分布式光纤声波传感器监测大容量气枪震源信号

MONITORING SIGNAL OF AIRGUN SOURCE WITH DISTRIBUTED ACOUSTIC SENSING

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