径向道域变步长采样叠前非稳态反褶积处理方法研究

摘要
参考文献
相关文章

全文: PDF (1297 KB) HTML ( KB) 输出: BibTeX | EndNote (RIS) 背景资料

摘要传统的非稳态褶积模型假设地震波是垂直入射的，而实际接收到的XT域地震数据不能满足这一假设条件。针对该问题，本文采用径向道变换技术，使地震数据在RT域能够广义上满足该假设条件；同时采用变步长采样双曲光滑法求取了考虑地层吸收衰减影响的非稳态反褶积因子，从而使径向道域变步长采样叠前非稳态反褶积综合了常规反褶积和反Q滤波的优点，实现了高精度、高分辨叠前非稳态反褶积。理论模型和实际资料处理结果表明，与常规非稳态反褶积方法相比，径向道域变步长采样叠前非稳态反褶积结果具有更高的分辨率，同相轴具有更好的横向连续性，更能有效恢复远炮检距和深层的地震数据。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	李芳
	王守东
	陈小宏
	刘国昌
	郑强

关键词：非稳态反褶积变步长采样径向道变换 Gabor变换衰减补偿

Abstract： The conventional nonstationary convolutional model assumes that the seismic signal is recorded at normal incidence. Raw shot gathers are far from this assumption because of the effects of offsets. Because of such problems, we propose a novel prestack nonstationary deconvolution approach. We introduce the radial trace (RT) transform to the nonstationary deconvolution, we estimate the nonstationary deconvolution factor with hyperbolic smoothing based on variable-step sampling (VSS) in the RT domain, and we obtain the high-resolution prestack nonstationary deconvolution data. The RT transform maps the shot record from the offset and traveltime coordinates to those of apparent velocity and traveltime. The ray paths of the traces in the RT better satisfy the assumptions of the convolutional model. The proposed method combines the advantages of stationary deconvolution and inverse Q filtering, without prior information for Q. The nonstationary deconvolution in the RT domain is more suitable than that in the space-time (XT) domain for prestack data because it is the generalized extension of normal incidence. Tests with synthetic and real data demonstrate that the proposed method is more effective in compensating for large-offset and deep data.

Key words： Nonstationary deconvolution Variable-step sampling Radial trace transform Gabor transform Attenuation compensation

收稿日期: 2013-07-15;

基金资助:

本研究由国家科技重大专项项目（编号：2011ZX05023-005-005）和国家自然科学基金（编号：41274137）联合资助。

引用本文:

李芳,王守东,陈小宏等. 径向道域变步长采样叠前非稳态反褶积处理方法研究[J]. 应用地球物理, 2013, 10(4): 423-432.

LI Fang,WANG Shou-Dong,CHEN Xiao-Hong et al. Prestack nonstationary deconvolution based on variable-step sampling in the radial trace domain[J]. APPLIED GEOPHYSICS, 2013, 10(4): 423-432.

[1]	Claerbout, J. F., 1975, Slant-stacks and radial traces: Stanford Exploration Project Report, 5, 1 - 12.
[2]	Claerbout, J. F., 1983, Ground roll and radial traces: Stanford Exploration Project Report, 35, 43 - 54.
[3]	Clarke, G. K. C., 1968, Time-varying deconvolution filters: Geophysics, 33, 936 - 944.
[4]	Griffiths, L. J., Smolka, F. R., and Trembly, L.D., 1977, Adaptive deconvolution: A new technique for processing time-varying seismic data: Geophysics, 42, 742 - 759.
[5]	Henley, D. C., 2003, Coherent noise attenuation in the radial trace domain: Geophysics, 68(4), 1408 - 1416.
[6]	Kormylo, J., and Mendel, J., 1978, One maximum likelihood detection and estimation of reflection coefficients: 48th Ann. Internat. Mtg, Soc. Expl. Geophys., Expanded Abstracts, Expanded Abstracts, 45 - 46.
[7]	Lamont, M. G., Hartley, B. M., and Uren, N. F., 1999, Multiple attenuation using the MMO and ISR preconditioning transforms: The leading Edge, 18(1), 110 - 114.
[8]	Liu, G. C., Chen, X. H., Li, J. Y., Du, J., and Song, J. W., 2011, Seismic noise attenuation using nonstationary polynominal fitting: Applied Geophysics, 8, 18 - 26.
[9]	Margrave, G. F., 1998, Theory of nonstationary linear filtering in the Fourier domain with application to time variant filtering: Geophysics, 63(1), 244- 259.
[10]	Margrave, G. F., Gibson, P. C., Grossman, et al, 2004, Gabor deconvolution: theory and practice: 66th Conference & Exhibition in Paris of France. EAGE Extended Abstracts, Z99.
[11]	Margrave, G. F., Lamoureux, M. P., and Henley, D. C., 2011, Gabor deconvolution: Estimating reflectivity by nonstationary deconvolution of seismic data: Geophysics, 76(3), 15 - 30.
[12]	Peacock, K. L., and Treitel, S., 1969, Predictive deconvolution: Theory and practice: Geophysics, 34, 155-169.
[13]	Robinson, E. A., 1954, Predictive decomposition of time series with applications to seismic exploration PhD thesis, Massachusetts Institute of Technology, America.
[14]	Robinson, E. A., 1967, Predictive decomposition of time series with application to seismic exploration: Geophysics, 32, 418 - 484.
[15]	Robinson, E. A., and Treitel, S., 1967, Principles of digital Wiener filtering: Geophysical Prospecting, 15(3), 311-332.
[16]	Taner, M. T., 1980, Long-period sea-floor Multiples and their suppression: Geophysical Prospecting, 28(1), 30 - 48.
[17]	Ulrych, T. J., 1971, Application of homomorphic deconvolution to seismology: Geophysics, 36(4), 650 - 660.
[18]	Wiener, N., 1949, Extrapolation, Interpolation, and Smoothing of Stationary time series: Journal of the American Statistical Association, 47(258), 319.
[19]	Wiggins, R. A., 1978, Minimum entropy deconvolution: Geoexploration, 16(1).
[20]	Zhang, C., and Ulrych, T. J., 2007, Seismic absorption compensation: A least-squares inverse scheme: Geophysics, 72(6), R109 - R114.

[1]	李皓，李国发，郭祥辉，孙夕平，王建富. 基于非稳态反演的气枪阵列子波方向性反褶积?[J]. 应用地球物理, 2019, 16(1): 124-132.
[2]	王万里，杨午阳，魏新建，何欣. 基于小波分频与径向道变换的联合压制面波方法[J]. 应用地球物理, 2017, 14(1): 96-104.
[3]	吴娟, 陈小宏, 白敏, 刘国昌. 基于吸收衰减补偿的多分量高斯束叠前深度偏移[J]. 应用地球物理, 2015, 12(2): 157-168.
[4]	陈颖频, 彭真明, 贺振华, 田琳, 张洞君. 基于自适应窗函数的最优分数域Gabor变换及其应用[J]. 应用地球物理, 2013, 10(3): 305-313.
[5]	王守东. 基于反演的衰减补偿方法[J]. 应用地球物理, 2011, 8(2): 150-157.
[6]	刘国昌, 陈小宏, 李景叶, 杜婧, 宋家文. 基于非稳态多项式拟合的地震噪声衰减方法研究[J]. 应用地球物理, 2011, 8(1): 18-26.