基于弹性参数加权统计的储层物性参数反演方法

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摘要储层物性参数的改变伴随着弹性参数某种程度的改变，而这种改变并非简单的线性关系。加上观测信息的缺失、重叠、噪声破坏及模型理想化等原因，致使这种改变关系的获取具有较大的不确定性。针对传统统计岩石物理物性参数反演方法的不足，以利用弹性参数反演储层物性参数为目的，依据贝叶斯反演框架，我们建立了新的储层物性参数目标反演函数。首先，采用兼具确定性与随机性特点的统计岩石物理模型，考虑到不同弹性参数间的精度存在差异，引入权重系数，建立起储层物性参数与弹性参数间的加权统计关系。其次，基于这种加权统计关系，结合马尔科夫链蒙特卡洛随机模拟技术产生储层物性参数、弹性参数随机联合样本空间作为目标函数求解样本空间。最后，建立解的快速求解准则，求取最大后验概率密度对应的储层物性参数取值作为最终解。实际应用表明，该方法具有较高的反演效率，应用前景较好。

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	桂金咏
	高建虎
	雍学善
	李胜军
	刘炳杨
	赵万金

关键词：储层物性参数反演加权统计贝叶斯随机模拟

Abstract： Variation of reservoir physical properties can cause changes in its elastic parameters. However, this is not a simple linear relation. Furthermore, the lack of observations, data overlap, noise interference, and idealized models increases the uncertainties of the inversion result. Thus, we propose an inversion method that is different from traditional statistical rock physics modeling. First, we use deterministic and stochastic rock physics models considering the uncertainties of elastic parameters obtained by prestack seismic inversion and introduce weighting coefficients to establish a weighted statistical relation between reservoir and elastic parameters. Second, based on the weighted statistical relation, we use Markov chain Monte Carlo simulations to generate the random joint distribution space of reservoir and elastic parameters that serves as a sample solution space of an objective function. Finally, we propose a fast solution criterion to maximize the posterior probability density and obtain reservoir parameters. The method has high efficiency and application potential.

Key words： Reservoir parameters inversion weighted statistics Bayesian framework stochastic simulation

收稿日期: 2015-06-08;

基金资助:

本研究由国家科技重大专项课题（编号：2011ZX05007-006)、国家973专项（编号：2013CB228604)、中国石油股份公司科技专项（编号：2014B-0610）联合资助。

引用本文:

桂金咏,高建虎,雍学善等. 基于弹性参数加权统计的储层物性参数反演方法[J]. 应用地球物理, 2015, 12(4): 523-532.

Gui Jin-Yong,Gao Jian-Hu,Yong Xue-Shan et al. Reservoir parameter inversion based on weighted statistics[J]. APPLIED GEOPHYSICS, 2015, 12(4): 523-532.

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