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Title: Porosity and formation pressure prediction from seismic data

Abstract

Seismic porosity and formation pressure logs are derived from seismic data exploiting novel characteristics of wavelet deconvolution and seismic inversion by modeling. In the first stage of wavelet deconvolution, the system wavelet is removed, and data are migrated to their true position. Thereafter, postmigration processing is performed in a deterministic manner using constraints derived from seismic and well data. The final result is the band-limited version of the reflectivity function. Subsequently, seismic inversion by modeling is accomplished iteratively, using the recursion expression that relates the acoustic impedance with the reflection coefficient. Missing frequencies between the high-frequency cut of the low-frequency acoustic impedance model and the low-frequency cut of the seismic data are also recovered iteratively. This feature provides better resolution through the acoustic impedance logs in time and depth. Velocity and pseudodensity logs are then derived using a relationship between densities and sonic velocities. Seismic porosity and formation pressure are computed against depth using the velocity and pseudodensity logs. Seismic porosities are calculated using bulk pseudodensities. Appropriate depth-variant constraints (matrix and fluid densities, shaliness factors) are generated from well-log data and gridded to produce constraint profiles in common-depth-point depth space. Formation pressure logs are calculated assuming that compressional velocity, density,more » and depth are proportional to formation pressure. The seismic porosity and formation pressure logs may be then interpreted to delineate reservoirs and to detect abnormally pressured zones. An example using real data illustrates the complete procedure followed for seismic porosity and formation log calculations.« less

Authors:
Publication Date:
Research Org.:
Geophysical Service Inc., Dallas, TX
OSTI Identifier:
5199516
Report Number(s):
CONF-860624-
Journal ID: CODEN: AAPGB
Resource Type:
Conference
Journal Name:
Am. Assoc. Pet. Geol., Bull.; (United States)
Additional Journal Information:
Journal Volume: 70:5; Conference: American Association of Petroleum Geologists annual meeting, Atlanta, GA, USA, 15 Jun 1986
Country of Publication:
United States
Language:
English
Subject:
02 PETROLEUM; PETROLEUM DEPOSITS; RESERVOIR ROCK; POROSITY; SEISMIC SURVEYS; DATA ANALYSIS; GEOLOGIC DEPOSITS; GEOPHYSICAL SURVEYS; MINERAL RESOURCES; RESOURCES; SURVEYS; 020200* - Petroleum- Reserves, Geology, & Exploration

Citation Formats

Martinez, R D. Porosity and formation pressure prediction from seismic data. United States: N. p., 1986. Web.
Martinez, R D. Porosity and formation pressure prediction from seismic data. United States.
Martinez, R D. Thu . "Porosity and formation pressure prediction from seismic data". United States.
@article{osti_5199516,
title = {Porosity and formation pressure prediction from seismic data},
author = {Martinez, R D},
abstractNote = {Seismic porosity and formation pressure logs are derived from seismic data exploiting novel characteristics of wavelet deconvolution and seismic inversion by modeling. In the first stage of wavelet deconvolution, the system wavelet is removed, and data are migrated to their true position. Thereafter, postmigration processing is performed in a deterministic manner using constraints derived from seismic and well data. The final result is the band-limited version of the reflectivity function. Subsequently, seismic inversion by modeling is accomplished iteratively, using the recursion expression that relates the acoustic impedance with the reflection coefficient. Missing frequencies between the high-frequency cut of the low-frequency acoustic impedance model and the low-frequency cut of the seismic data are also recovered iteratively. This feature provides better resolution through the acoustic impedance logs in time and depth. Velocity and pseudodensity logs are then derived using a relationship between densities and sonic velocities. Seismic porosity and formation pressure are computed against depth using the velocity and pseudodensity logs. Seismic porosities are calculated using bulk pseudodensities. Appropriate depth-variant constraints (matrix and fluid densities, shaliness factors) are generated from well-log data and gridded to produce constraint profiles in common-depth-point depth space. Formation pressure logs are calculated assuming that compressional velocity, density, and depth are proportional to formation pressure. The seismic porosity and formation pressure logs may be then interpreted to delineate reservoirs and to detect abnormally pressured zones. An example using real data illustrates the complete procedure followed for seismic porosity and formation log calculations.},
doi = {},
journal = {Am. Assoc. Pet. Geol., Bull.; (United States)},
number = ,
volume = 70:5,
place = {United States},
year = {1986},
month = {5}
}

Conference:
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