Summary
The wavelet-transform (WT) method has been applied to logs to extract
reservoir-fluid information. In addition to the time (depth)/frequency analysis
generally performed by the wavelet method, we also have performed energy
spectral analysis for time/frequency-domain signals by the WT method. We have
further developed a new method to identify reservoir fluid by setting up a
correlation between the energy spectra and reservoir fluid. We have processed
42 models from an oil field in China using this method and have subsequently
applied these rules to interpret reservoir layers. It is found that
identifications by use of this method are in very good agreement with the
results of well tests.
Introduction
An important log-analysis application is determining reservoir-fluid
properties. It is common practice to calculate the water and oil saturations of
reservoir formations by use of electrical logs. With the development of
well-logging technology, a number of methods have been developed for
reservoir-fluid typing with well logs (Hou 2002; Geng et al. 1983; Dahlberg and
Ference 1984). A recent report has also described reservoir-fluid typing by the
T2 differential spectrum from nuclear-magnetic-resonance
(NMR) logs (Coates et al. 2001). However, because of the interference from
vugs, fractures, clay content, and mud-filtrate invasion, the reservoir-fluid
information contained in well logs is often concealed. The reliability of these
log interpretations is thus limited in many cases. Therefore, it is desirable
to find a more reliable and consistent way of reservoir-fluid typing with well
logs. In this paper, we present a new method using the WT for fluid typing with
well logs.
The WT technique was developed with the localization idea from Gabor’s
short-time Fourier analysis and has been expanded further. Wavelets provide the
ability to perform local analysis (i.e., analyze a small portion of a larger
signal) (Daubechies 1992).This localized analysis represents the next logical
step: a windowing technique with variable-sized regions. Wavelet analysis
allows the use of long time intervals, where more-precise low-frequency
information is wanted, and shorter intervals, where high-frequency information
is needed. Wavelet analysis is capable of revealing aspects of data that other
signal-analysis techniques miss: aspects such as trends, breakdown points,
discontinuities in higher derivatives, and self-similarity. In
well-logging-data processing, wavelet analysis has been used to identify
formation boundaries, estimate reservoir parameters, and increase vertical
resolution (Lu and Horne 2000; Panda et al. 1996; Jiao et al. 1999; Barchiesi
and Gharbi 1999). For data interpretation, however, the identification of
hydrocarbon-bearing zones by wavelet analysis is still under investigation. In
this study, we have developed a technique of wavelet-energy-spectrum analysis
(WESA) to identify reservoir-fluid types. We have applied this technique to
field-data interpretation and have achieved very good results.
© 2006. Society of Petroleum Engineers
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History
- Original manuscript received:
21 December 2004
- Revised manuscript received:
3 October 2005
- Manuscript approved:
18 July 2006
- Version of record:
20 October 2006
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