Analysis of acquisition parameters and geometry quality
Zhao Hu1,2, Xu Hao3, Di Zhi-Xin4, Zhang Jin-Miao5, and Liu Zhi-Peng5
1. Southwest Petroleum University, Sichuan Province Natural Gas Geology Key Laboratory, Chengdu 610500, China.
2. School of Geoscience and Technology in Southwest Petroleum University, Chengdu 610500, China.
3. Petroleum Exploration and Production Research Institute, SINOPEC Northwest Oilfield Company, Urumqi 830011, China.
4. SINOPEC Geophysical Corporation, Research Center, Beijing 100020, China.
5. CNOOC Research Institute, Beijing 100028, China.
Abstract:
High-quality seismic geometry is the key to obtain high-quality seismic data, and can affect the accuracy of data processing and imaging. Based on the analysis of the relationship between the quality of the geometry and the four acquisition parameters (the number of traces, shot line spacing, and the space and number of receiver lines), a quality evaluation method of the geometry based on comprehensive quality factor (CQF) is proposed, and the relationship between the geometry quality and the four parameters is given. We use field data collected in an oil field in Western China with complex geology: First we use a wide azimuth geometry. Then, we calculate the relationship curve between geometry and data quality by varying each parameter while keeping the rest fixed. and the analysis results are given by using the CQF evaluation method. The results show that the shot-line spacing has the greatest effect on the quality of the geometry, and the increase of the receiver line spacing can appropriately improve the quality of the geometry, and the increase of the number of receiving traces can improve the geometry quality. The different acquisition parameters have different effects on the imaging quality of shallow and deep events. The model forward and prestack depth migration are used to generate prestack depth migration profiles with different acquisition parameters. The imaging results are consistent with the above calculated results. According to the depth of the target layer, the quality factor evaluation method is applied to guide the design of the geometry and optimize the acquisition parameters to improve the imaging accuracy of seismic data.
. Analysis of acquisition parameters and geometry quality[J]. APPLIED GEOPHYSICS, 2018, 15(3-4): 413-419.
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2018, Vol. 15 
