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Predicting the distribution of reservoirs by combining variable wavelet model of seismograms with wavelet edge analysis and modeling

Predicting the distribution of reservoirs by combining variable wavelet model of seismograms with wavelet edge analysis and modeling
Predicting the distribution of reservoirs by combining variable wavelet model of seismograms with wavelet edge analysis and modeling
Reservoir prediction with its unique role in oil and gas fields is constantly facing new challenges, such as high-resolution seismic data and fast-accurate impedance inversion are needed. Generally, conventional methods used to enhance the resolution of seismic data, for example the spectral whitening, sometimes called balancing or broadening, is hard to yield valuable results as the seismic wavelets change during traveling subsurface. Besides, impedance inversion used in reservoir such as acoustic impedance inversion (AII) also confronts problem—low computational efficiency when more geological and geophysical parameters are taken into consideration in the modeling inversion. Based on these questions, in this study, a joint approach is presented. The first approach is the variable wavelet model of seismograms (VWMS), which is carried out by a series of processes such as time partition and frequency domain processing, to enhance the resolution of the seismic traces. Another approach that can improve the computational efficiency of the AII is the acoustic impedance inversion based wavelet edge analysis and modeling (AII-WEAM). In this approach, the algorithms of the AII were replaced by the modified very fast simulated annealing (MVFSA), to improve the inversed speed. By using a gas reservoir predicting example, we show that the joint approaches produce results that are feasible and reliable after comparing with the well data. Hence, these joint approaches have great potential to be the next-generation tools for reservoir description and prediction.
Reservoir simulation, Acoustic impedance inversion, Wavelet edge analysis, Simulated annealing, Seismic data, Enhancing resolution
0926-9851
116-123
Xie, Yujiang
77c46c7b-1aa6-4534-bca1-8c6a3dd40705
Liu, Gao
b9f49108-fe31-433c-893f-851c67e693f8
Xie, Yujiang
77c46c7b-1aa6-4534-bca1-8c6a3dd40705
Liu, Gao
b9f49108-fe31-433c-893f-851c67e693f8

Xie, Yujiang and Liu, Gao (2014) Predicting the distribution of reservoirs by combining variable wavelet model of seismograms with wavelet edge analysis and modeling. Journal of Applied Geophysics, 101, 116-123. (doi:10.1016/j.jappgeo.2013.12.005).

Record type: Article

Abstract

Reservoir prediction with its unique role in oil and gas fields is constantly facing new challenges, such as high-resolution seismic data and fast-accurate impedance inversion are needed. Generally, conventional methods used to enhance the resolution of seismic data, for example the spectral whitening, sometimes called balancing or broadening, is hard to yield valuable results as the seismic wavelets change during traveling subsurface. Besides, impedance inversion used in reservoir such as acoustic impedance inversion (AII) also confronts problem—low computational efficiency when more geological and geophysical parameters are taken into consideration in the modeling inversion. Based on these questions, in this study, a joint approach is presented. The first approach is the variable wavelet model of seismograms (VWMS), which is carried out by a series of processes such as time partition and frequency domain processing, to enhance the resolution of the seismic traces. Another approach that can improve the computational efficiency of the AII is the acoustic impedance inversion based wavelet edge analysis and modeling (AII-WEAM). In this approach, the algorithms of the AII were replaced by the modified very fast simulated annealing (MVFSA), to improve the inversed speed. By using a gas reservoir predicting example, we show that the joint approaches produce results that are feasible and reliable after comparing with the well data. Hence, these joint approaches have great potential to be the next-generation tools for reservoir description and prediction.

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More information

Published date: 1 February 2014
Additional Information: Copyright © 2013 Elsevier B.V. All rights reserved.
Keywords: Reservoir simulation, Acoustic impedance inversion, Wavelet edge analysis, Simulated annealing, Seismic data, Enhancing resolution

Identifiers

Local EPrints ID: 469852
URI: http://eprints.soton.ac.uk/id/eprint/469852
DOI: doi:10.1016/j.jappgeo.2013.12.005
ISSN: 0926-9851
PURE UUID: d3357bca-d451-4c42-a058-5d2f32e64725

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Date deposited: 27 Sep 2022 16:39
Last modified: 16 Mar 2024 21:18

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Contributors

Author: Yujiang Xie
Author: Gao Liu

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