Petrophysical parameters prediction and uncertainty analysis in tight sandstone reservoirs using Bayesian inversion method

Petrophysical parameters are of great importance in the evaluation and characterization for reservoirs, especially for the unconventional reservoirs with complex properties. The geophysical inversion is an efficient and economic method to obtain the petrophysical parameters. In this paper, Bayesian...

Full description

Saved in:
Bibliographic Details
Published in:Journal of natural gas science and engineering 2018-07, Vol.55, p.431-443
Main Authors: Qin, Ruidong, Pan, Heping, Zhao, Peiqiang, Deng, Chengxiang, Peng, Ling, Liu, Yaqian, Kouroura, Mohamed
Format: Article
Language:English
Subjects:
Bayesian inversion
Conventional well logs
Markov chain Monte Carlo
Petrophysical parameters
Tight sandstone reservoirs
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Petrophysical parameters are of great importance in the evaluation and characterization for reservoirs, especially for the unconventional reservoirs with complex properties. The geophysical inversion is an efficient and economic method to obtain the petrophysical parameters. In this paper, Bayesian inversion method is presented to predict petrophysical model with conventional well logs. Statistical analysis results of accepted Markov chain Monte Carlo (MCMC) samples are used to study the uncertainty of forecasted parameters, since the MCMC is a powerful approach to obtain adequate samples obeying the posterior distribution of Bayesian inversion. The proposed method is applied to reservoirs of the Xiashihezi Formation which are typical tight sandstone layers in the Ordos Basin. Model prediction and corresponding uncertainty analysis are presented in detail at a specific depth. The interactive effects of multiple petrophysical parameters are investigated by correlation coefficients. Then, the accuracy and reliability of predicted model is validated by both forward log responses and core data of the whole depth interval. According to the results and discussions, it can be concluded that: (1) a reasonable prior information of model parameters will simplify the inversion problem, which provides much conveniences of statistical analysis of the MCMC samples; (2) the weak correlation between each two petrophysical parameters indicates that it is reasonable and feasible to disregard dependence of parameters; (3) synthetic logs calculated by predicted model are in good agreement with observed well logs, which implies the precision and credibility of Bayesian inversion; (4) the predicted porosity, permeability and minerals content are consistent with core data, verifying the effectiveness and reliability of proposed method and inversion results; (5) it is an advantage of Bayesian inversion to locate the most probable reservoirs with the extreme value. •An efficient inversion method is introduced to predict petrophysical parameters with conventional well logs.•A case study illustrates that Bayesian inversion results are precise and credible for the tight sandstone reservoirs.•Core data, as prior information, is used to restrain the Bayesian inversion results.•The Bayesian inversion results can provide both best-fitting model parameters and probability.
ISSN:1875-5100
DOI:10.1016/j.jngse.2018.04.031