叠前FAGVO计算方法及应用

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摘要地下储层含烃类流体引起地震信号频率的衰减，目前对叠后地震资料的频率衰减研究较多，但是涉及叠前道集上的频率衰减研究较少。作者综合叠前AVO的计算公式及频率衰减积分计算式，对叠前部分叠加角道集的频率衰减梯度差值 (Frequency Attenuation Gradient vs.Offset，简称FAGVO) 的计算公式进行了推导，显示完全弹性介质的FAGVO为零，粘弹性介质的FAGVO为负值，且FAGVO的绝对值大小与介质粘度、频率变化、反射系数及高频的衰减有关。FAGVO可以消除部分影响地下岩层频率变化因素的干扰，从而突出含烃储层频率衰减梯度的异常，达到利用叠前部分叠加道集进行含烃类流体检测的目的。该方法经过二维波动方程正演模型的验证，检测效果理想，且该方法对钻井信息的依赖较小，可应用于油气地震勘探阶段，尤其是无井区的勘探，既经济又高效。

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关键词： FAGVO 频率衰减含烃类储层叠前道集部分叠加道集

Abstract： Frequency attenuation occurs when seismic waves propagate through the porous reservoirs containing hydrocarbons. Current researches on the seismic frequency attenuation mainly focus on the post-stack domain instead of the prestack domain. Here we propose the frequency attenuation gradient vs. offset (FAGVO) based on the amplitude variation with offset and frequency attenuation integral equations. We derive the FAGVO equation that equals to zero in a full-elastic medium and is negative in a viscoelastic medium. FAGVO is affected by the viscosity of the medium, the coefficients of reflection, the frequency variation, and high-frequency attenuation. FAGVO uses the differences of partially stacked data to decrease the interference caused by subsurface strata affecting the frequency attenuation, highlights the frequency attenuation gradient anomalies in hydrocarbon-bearing reservoir pores, and finally realizes the hydrocarbon fluid identification. The method was verified using a two-dimensional wave equation forward model and was found to be cost effective. Furthermore, the method does not require well information, which can be applied in the stage of seismic exploration, especially, in the exploration of a none-well project.

Key words： FAGVO frequency attenuation hydrocarbon reservoir prestack partial stack

收稿日期: 2016-05-06;

基金资助:

本研究由国家科技重大专项课题（编号：2016ZX05003-003）和国家高技术研究发展计划（863计划）（编号：2013AA064201）资助。

引用本文:

. 叠前FAGVO计算方法及应用[J]. 应用地球物理, 2016, 13(4): 641-648.

. Calculation method of prestack FAGVO and its applications[J]. APPLIED GEOPHYSICS, 2016, 13(4): 641-648.

[1]	Aki, K., and Richards, P. G., 1980, Quantitative seismology: Theory and methods: W. H. Freeman and Co., 100−170.
[2]	Barnes, A. E., 1993, Instantaneous spectral bandwidth and dominant frequency with applications to seismic reflection data: Geophysics, 58(3), 419−428.
[3]	Chapman, M., Liu, E. and Li, X. Y., 2006, The influence of fluid-sensitive dispersion and attenuation on AVO analysis: Geophys. J. Int., 167, 89−105.
[4]	Chen, S. Q., Li, X. Y. and Wang, S. X., 2012a, The analysis of frequency-dependent characteristics for fluid detection: A physical model experiment: Applied Geophysis, 9, 195−206.
[5]	Chen, X. H., He, Z. H., Zhu, S. X., et al., 2012b, Seismic low-frequency-based calculation of reservoir fluid mobility and its applications: Applied Geophysis, 9, 326−332.
[6]	Cobos, C., and Han, D. H., 2004, Can we use frequency shift due to attenuation for fizz water discrimination: 74th Annual Meeting, SEG, Extended Abstract, 23, 1630−1633.
[7]	Fatti, J. L., Vail, P. J., Smisth, G. C., et al., 1994, Detection of gas in sandstone reservoirs using AVO analysis: a 3-D seismic case history using the Geostack technique: Geophysics, 59(9), 1362−1376.
[8]	Goodway, B., Chen, T., and Downton, J., 1997, Improved AVO fluid detection and lithology discrimination using lame petro-physical parameters: 67th Annual International Meeting, SEG, Extended Abstracts, 183−186.
[9]	Hou, B., Chen, X. H., Li, J. Y., and Zhang, X. Z., 2011, Multi-wave amplitude-preserved AVO modeling considering wave propagation effects: Applied Geophysics, 8(3), 207−216.
[10]	Liu, C., Li, B. N., Zhao, X., Liu, Y., and Lu, Q., 2014, Fluid identification based on frequency-dependent AVO attribute inversion in multi-scale fracture media: Applied Geophysics, 11(4), 384−394.
[11]	Ma, J. Q., and Geng, J. H., 2013, Cauchy prior distribution-based AVO elastic parameter estimation via weakly nonlinear waveform inversion: Applied Geophysics, 10(4), 442−452.
[12]	Ricker, N., 1940, The form and nature of seismic waves and the structure of seismograms: Geophysics, 5, 348−366.
[13]	Shuey, R. T., 1985, Amplification of the Zoeppritz’s equations: Geophysics, 50(4), 60−614.
[14]	Sun, L. P., Zheng, X. D., Li, J. S., and Hao, S., 2009, Thin-bed thickness calculation equation and its approximation using peak frequency: Applied Geophysics, 6(3), 234−240.
[15]	Tai, S. H., Puryear, C., and Castagna, J. P., 2009, Local frequency as a direct hydrocarbon indicator: SEG Houston Int’l Exposition and Annual Meeting, 2160−2164.
[16]	Wang, P., and Hu, T. Y., 2011, AVO approximation foe PS-wave and its application in PP/PS joint inversion: Applied Geophysics, 8(3), 189−196.
[17]	Zhang, C. G., Tadeusz, J., and Ulrych, T. J., 2002, Estimation of quality factors from CMP records: Geophysics, 67(5), 1542−1547.
[18]	Zoeppritz, K., 1919, On the reflection and propagation of seismic waves: Gottinger Nachrichten, I, 66−84.

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