Detection of Low Velocity Geological Anomalous Body Using Surface Wave Transverse High Resolution Technology
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摘要: 为了能在狭窄空间提高面波的横向分辨能力,利用线性拉冬变换提取地震波记录中的面波,采用相邻两道相位差法计算面波的频散曲线,再用半波长解释方法得到拟二维面波相速度剖面.在随机介质中建立低速异常体模型,在一个短排列的情况下,通过对波动方程有限差分数值模拟的地震波记录进行数据处理,在速度剖面中低速异常体区域明显,位置准确.将此技术应用到郑州市地下防空洞的探测以及黄河大堤渗漏的探测中,寻找到了防空洞的位置及渗水通道.该技术具有很高的横向分辨率,适用于城市狭窄空间地面无损探测.Abstract: In order to improve surface wave in the narrow space of the lateral resolving power, a method is proposed to the two-dimensional surface wave phase velocity profile, firstly using linear Radon transform to extract the surface waves in seismic records, then using two adjacent phase difference method to calculate the surface wave dispersion curves, and finally explaining it with half wave. A model of abnormal body at low speed is established in random medium, in the case of a short order. Through data processing of seismic wave records from finite difference numerical simulation of wave equation, it is found that the area of low-velocity abnormal body in velocity profile is obvious and its location is accurate. This technique has been applied to the detection of underground air-raid shelters in Zhengzhou City and the detection of seepage in the Yellow River levee, and the positions of air-raid shelters and seepage channels have been found. This technique has high lateral resolution and is suitable for non-destructive ground detection in urban narrow space.
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图 3 模型一的地震波记录
a.左边炮原始记录;b.左边炮提取的面波记录;c.右边炮原始记录;d.右边炮提取的面波记录
Fig. 3. Seismic wave recording of model 1
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Al-Hunaidi, M. O., 1994. Analysis of Dispersed Multi-Mode Signals of the SASW Method Using the Multiple Filter/Crosscorrelation Technique. Soil Dynamics and Earthquake Engineering, 13(1): 13-24. https://doi.org/10.1016/0267-7261(94)90037-X Chen, J., Xiong, Z. Q., Zhang, D. Z., et al., 2018. The Extract Dispersion Curves of Rayleigh Surface Wave Based on Multiple Filtering Method. Chinese Journal of Engineering Geophysics, 15(4): 411-417 (in Chinese with English abstract). Chen, Q., Xiong, Z. Q., Zhang, D. Z., 2021. Studly of Rayleigh Wave Dispersion Curves Based on the Combination of Phase Difference Method and Multiple Filtering Method. Chinese Journal of Engineering Geophysics, 18(6): 856-866 (in Chinese with English abstract). doi: 10.3969/j.issn.1672-7940.2021.06.007 Huang, J. Z., Zhang, X. Q., Guan, X. P., 1995. Application of RSM-16H Dynamic Measuring Instrument in Soil and Rock Mass Detection by Surface Wave Method. Rock and Soil Mechanics, 16(2): 83-89 (in Chinese with English abstract). Karray, M., Lefebvre, G., 2009. Techniques for Mode Separation in Rayleigh Wave Testing. Soil Dynamics and Earthquake Engineering, 29(4): 607-619. https://doi.org/10.1016/j.soildyn.2008.07.005 Ke, L. M., Li, H., Feng, S. K., et al., 2020. Preliminary Study on Compactness Detection of Rock-Filled Dam Based on High-Density Surface Wave Technology. Journal of China Institute of Water Resources and Hydropower Research, 18(5): 337-346 (in Chinese with English abstract). Lei, X. Y., Li, Z. W., Huang, Y., 2008. Application of Stable Surface Wave to the Exploration of Soft Soil. Geotechnical Investigation & Surveying, 36(3): 45-48 (in Chinese with English abstract). Li, Q. L., Zhang, H., Lei, X. D., et al., 2022. Analysis of Internal Structure of Slope by Using Multi-Channel Transient Surface Wave Exploration and Microtremor Survey. Geophysical and Geochemical Exploration, 46(1) : 258-267 (in Chinese with English abstract). Liu, X. F., Jiang, W. L., Wang, X. M., et al., 2020. The Applied Research on the Surface Wave Exploration under Complex Geological Conditions. Geophysical and Geochemical Exploration, 44(2): 449-455 (in Chinese with English abstract). Liu, X. P., Yin, K. L., Xiao, C. G., et al., 2024. Meteorological Early Warning of Landslide based on I-D-R Threshold Model. Earth Science, 49(3): 1039-1051 (in Chinese with English abstract). Liu, Y. Z., Wang, Z. D., 1996. Data Acquisition and Processing System of Transient Surface Wave Method and Its Application Example. Geophysical and Geochemical Exploration, 20(1): 28-34 (in Chinese with English abstract). Ma, J. Q., Li, Q. C., Fan, J. S., et al., 2010. Rayleigh Wave Dispersion Analysis Based on S Transform. Journal of Earth Sciences and Environment, 32(3): 319-323 (in Chinese with English abstract). Stockwell, R. G., Mansinha, L., Lowe, R. P., 1996. Localization of the Complex Spectrum: The S Transform. IEEE Transactions on Signal Processing, 44(4): 998-1001. https://doi.org/10.1109/78.492555 Thorson, J. R., Claerbout, J. F., 1985. Velocity-Stack and Slant-Stack Stochastic Inversion. Geophysics, 50(12): 2727-2741. https://doi.org/10.1190/1.1441893 Tian, B. Q., Ding, Z. F., 2021. Review and Prospect Prediction for Microtremor Survey Method. Progress in Geophysics, 36(3): 1306-1316 (in Chinese with English abstract). Wang, X. L., 2020. Application of 2D Transient Surface Wave in the Detection of Hidden Karst at the Bottom of the Tunnel. High Speed Railway Technology, 11(3): 46-50 (in Chinese with English abstract). Xu, H. Q., 2009. Study on Dispersion Characteristics of Rayleigh Surface Wave and Its Application (Dissertation). Chengdu Univerisity of Technology, Chengdu (in Chinese with English abstract). Yang, Z., Li, Y., Zhao, F., et al., 2022. Fine Detection of Shallow Coal Seam Mined-out Area by Multichannel Analysis of Surface Waves. Journal of Mining Science and Technology, 7(1): 113-122 (in Chinese with English abstract). http://www.semanticscholar.org/paper/18da81405739c7956bcd4e9dae8b65d3b18440a8 Yin, X. F., Xu, H. R., Xia, J. H., et al., 2018. A Travel-Time Tomography Method for Improving Horizontal Resolution of High-Frequency Surface-Wave Exploration. Chinese Journal of Geophysics, 61(6): 2380-2395 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTotal-DQWX201806019.htm Yu, D. K., Wei, L., 2020. Research on the Application of Surface Wave Technology in Foundation Reinforcement. Exploration Project in the West, 8: 21-25 (in Chinese with English abstract). Zhang, Y. P., Rong, X., Ge, L. J., et al., 2021. Application of Surface Wave Method in the Investigation of Lanxi Ancient City Wall. Shaanxi Water Resources, (5): 14-17 (in Chinese with English abstract). 陈杰, 熊章强, 张大洲, 等, 2018. 基于多模式的多重滤波方法提取瑞雷面波频散曲线. 工程地球物理学报, 15(4): 411-417. 谌强, 熊章强, 张大洲, 2021. 基于相位差法和多重滤波法结合的瑞雷面波频散曲线研究. 工程地球物理学报, 18(6): 856-866. 黄嘉正, 张学强, 关小平, 1995. RSM-16H动测仪在面波法岩土体检测中的应用. 岩土力学, 16(2): 83-89. 克里木, 李辉, 冯少孔, 等, 2020. 基于高密度面波技术的堆石坝密实度检测初探. 中国水利水电科学研究院学报, 18(5): 337-346. 雷旭友, 李正文, 黄宇, 2008. 稳态面波在软土勘察中的应用. 工程勘察, 36(3): 45-48. 李巧灵, 张辉, 雷晓东, 等, 2022. 综合利用多道瞬态面波和微动探测分析斜坡内部结构. 物探与化探, 46(1): 258-267. 刘现锋, 姜文龙, 王旭明, 等, 2020. 复杂地质条件下的面波探测技术应用研究. 物探与化探, 44(2): 449-455. 刘谢攀, 殷坤龙, 肖常贵, 等, 2024. 基于I-D-R阈值模型的滑坡气象预警. 地球科学, 49(3): 1039-1051. doi: 10.3799/dqkx.2022.233 刘云祯, 王振东, 1996. 瞬态面波法的数据采集处理系统及其应用实例. 物探与化探, 20(1): 28-34. 马见青, 李庆春, 樊金生, 等, 2010. 基于S变换的瑞利面波频散分析. 地球科学与环境学报, 32(3): 319-323. 田宝卿, 丁志峰, 2021. 微动探测方法研究进展与展望. 地球物理学进展, 36(3): 1306-1316. 王先龙, 2020. 二维瞬态面波在隧底隐伏岩溶探测中的应用. 高速铁路技术, 11(3): 46-50. 徐华全, 2009. 瑞雷面波的频散特征研究及应用(硕士学位论文). 成都: 成都理工大学. 杨智, 李宇, 赵飞, 等, 2022. 面波多道分析法精细探测浅部煤层采空区应用研究. 矿业科学学报, 7(1): 113-122. 尹晓菲, 胥鸿睿, 夏江海, 等, 2018. 一种基于层析成像技术提高浅地表面波勘探水平分辨率的方法. 地球物理学报, 61(6): 2380-2395. 于东凯, 魏亮, 2020. 面波技术在地基加固中的应用研究. 西部探矿工程, 8: 21-25. 张瑜鹏, 荣鑫, 葛龙进, 等, 2021. 面波法在兰溪古城墙工程勘察中的应用. 陕西水利, (5): 14-17. -
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