[an error occurred while processing this directive] ������� 2017, 36(3) 931-940 DOI:   10.3969/j.issn.1004-5589.2017.03.026  ISSN: 1004-5589 CN: 22-1111/P
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PubMed
Article by Sun H
Article by Qin Y
Article by Bai T
Article by Qian P
Article by Xu K
Article by Liu Y
Article by Jiang H
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3. �й�ʯ����Ȼ���ɷ����޹�˾�ɺ�����ֹ�˾��ɹ����о�Ժ, �����̽� 124010;
4. ���ִ�ѧ������ѧ���������ѧԺ, ���� 130026
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Research on joint microseismic monitoring of surface and borehole using amplitude stacking
SUN Hai-lin1, QIN Yue-shuang2, BAI Tian-zeng1, QIAN Peng3, XU Ke-bin1, LIU Yu-hai1, JIANG Hai-yu4
1. Downhole Services Company, BHDC, Tianjin 300457, China;
2. Exploration Department, Daqing Oilfield Company Ltd, Daqing 163453, Heilongjiang, China;
3. Drilling and Production Technology Research Institute, Liaohe Oilfield Branch Company of PetroChina Co Ltd, Panjin 124010, Liaoning, China;
4. College of Instrumentation and Electrical Engineering, Jilin University, Changchun 130026, China
Abstract: The main drawback of microseismic surface monitoring is the lack of vertical positioning resolution, whereas the borehole monitoring is with the problem of low lateral resolution. In this study, the authors improve the reliability of microseismic positioning by means of joint monitoring of surface and borehole, and the noise is suppressed by amplitude stacking method. The feasibility of the method is demonstrated by the inversion experiments of three-dimensional seismic data. The result of source locations from inversion are consistent with the actual source points. In this study, a hydraulic fracturing monitoring in Ningwu Basin of Shanxi is taken as an example, it is proved that the proposed method is feasible in practical application.
Keywords: microseismic monitoring   amplitude stacking   joint microseismic monitoring of surface and borehole  
�ո����� 2016-11-01 �޻����� 2017-08-27 ����淢������  
DOI: 10.3969/j.issn.1004-5589.2017.03.026
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