More difficulties are now expected in exploring economically valuable reservoirs
because most reservoirs have been already developed since beginning seismic exploration
of the subsurface. In order to efficiently analyze heterogeneous fine-scale properties
in subsurface layers, one ongoing challenge is accurately upscaling fine-scale
(high frequency) logging measurements to coarse-scale data, such as surface seismic
images. In addition, numerically efficient modeling cannot use models defined on the
scale of log data. At this point, we need an upscaling method replaces the small scale
data with simple large scale models. However, numerous unavoidable uncertainties
still exist in the upscaling process, and these problems have been an important emphasis
in geophysics for years. Regarding upscaling problems, there are predictable
or unpredictable uncertainties in upscaling processes; such as, an averaging method,
an upscaling algorithm, analysis of results, and so forth.
To minimize the uncertainties, a Bayesian framework could be a useful tool for
providing the posterior information to give a better estimate for a chosen model
with a conditional probability. In addition, the likelihood of a Bayesian framework
plays an important role in quantifying misfits between the measured data and the
calculated parameters. Therefore, Bayesian methodology can provide a good solution
for quantification of uncertainties in upscaling.
When analyzing many uncertainties in porosities, wave velocities, densities, and
thicknesses of rocks through upscaling well log data, the Markov Chain Monte Carlo
(MCMC) method is a potentially beneficial tool that uses randomly generated parameters
with a Bayesian framework producing the posterior information. In addition,
the method provides reliable model parameters to estimate economic values of hydrocarbon
reservoirs, even though log data include numerous unknown factors due to
geological heterogeneity. In this thesis, fine layered well log data from the North Sea
were selected with a depth range of 1600m to 1740m for upscaling using an MCMC implementation. The results allow us to automatically identify important depths
where interfaces should be located, along with quantitative estimates of uncertainty
in data. Specifically, interfaces in the example are required near depths of 1,650m,
1,695m, 1,710m, and 1,725m. Therefore, the number and location of blocked layers
can be effectively quantified in spite of uncertainties in upscaling log data.
| Identifer | oai:union.ndltd.org:tamu.edu/oai:repository.tamu.edu:1969.1/ETD-TAMU-2009-05-680 |
| Date | 16 January 2010 |
| Creators | Hwang, Kyubum |
| Contributors | Gibson, Richard L. |
| Source Sets | Texas A and M University |
| Language | en_US |
| Detected Language | English |
| Type | Book, Thesis, Electronic Thesis |
| Format | application/pdf |
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