Low frequency component of seismic data estimation and its application in seismic inversion

Acoustic impedance (AI) from seismic inversion can indicate rock properties and can be used, when combined with rock physics, to predict reservoir parameters, such as porosity. Solutions to seismic inversion problem are almost nonunique due to the limited bandwidth of seismic data. Additional constraints from well log data and geology are needed to arrive at a reasonable solution. In this paper, sedimentary facies is used to reduce the uncertainty in inversion and rock physics modeling; the results not only agree with seismic data, but also conform to geology. A reservoir prediction method, which incorporates seismic data, well logs, rock physics and sedimentary facies, is proposed. AI was first derived by constrained sparse spike inversion (CSSI) using a sedimentary facies dependent low-frequency model, and then was transformed to reservoir parameters by sequential simulation, statistical rock physics and [Formula: see text]-model. Two numerical experiments using synthetic model and real data indicated that the sedimentary facies information may help to obtain a more reasonable prediction.

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Accuracy of wavelets, seismic inversion, and thin-bed resolution

Interpretation ◽

10.1190/int-2017-0023.1 ◽

2017 ◽

Vol 5 (4) ◽

pp. T523-T530

Author(s):

Ehsan Zabihi Naeini ◽

Mark Sams

Keyword(s):

Seismic Data ◽

Reservoir Characterization ◽

Low Frequency ◽

Seismic Inversion ◽

Inversion Method ◽

Frequency Content ◽

Frequency Model ◽

North West ◽

The North ◽

Well Data

Broadband reprocessed seismic data from the North West Shelf of Australia were inverted using wavelets estimated with a conventional approach. The inversion method applied was a facies-based inversion, in which the low-frequency model is a product of the inversion process itself, constrained by facies-dependent input trends, the resultant facies distribution, and the match to the seismic. The results identified the presence of a gas reservoir that had recently been confirmed through drilling. The reservoir is thin, with up to 15 ms of maximum thickness. The bandwidth of the seismic data is approximately 5–70 Hz, and the well data used to extract the wavelet used in the inversion are only 400 ms long. As such, there was little control on the lowest frequencies of the wavelet. Different wavelets were subsequently estimated using a variety of new techniques that attempt to address the limitations of short well-log segments and low-frequency seismic. The revised inversion showed greater gas-sand continuity and an extension of the reservoir at one flank. Noise-free synthetic examples indicate that thin-bed delineation can depend on the accuracy of the low-frequency content of the wavelets used for inversion. Underestimation of the low-frequency contents can result in missing thin beds, whereas underestimation of high frequencies can introduce false thin beds. Therefore, it is very important to correctly capture the full frequency content of the seismic data in terms of the amplitude and phase spectra of the estimated wavelets, which subsequently leads to a more accurate thin-bed reservoir characterization through inversion.

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Broadband Seismic Inversion for Low-Frequency Component of the Model Parameter

IEEE Transactions on Geoscience and Remote Sensing ◽

10.1109/tgrs.2018.2810845 ◽

2018 ◽

Vol 56 (9) ◽

pp. 5177-5184 ◽

Cited By ~ 6

Author(s):

Zhaoyun Zong ◽

Yurong Wang ◽

Kun Li ◽

Xingyao Yin

Keyword(s):

Low Frequency ◽

Frequency Component ◽

Seismic Inversion ◽

Model Parameter

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Blind Inversion of Multidimensional Seismic Data Using Sequential Tikhonov and Total Variation Regularizations (STTVR)

Geophysics ◽

10.1190/geo2020-0692.1 ◽

2021 ◽

pp. 1-56

Author(s):

Saber jahanjooy ◽

Mohammad Ali Riahi ◽

Hamed Ghanbarnejad Moghanloo

Keyword(s):

Total Variation ◽

Tikhonov Regularization ◽

Seismic Data ◽

Low Frequency ◽

Seismic Inversion ◽

Earth Model ◽

Rapid Changes ◽

Nonlinear Relation ◽

Ill Posed ◽

Seismic Sections

The acoustic impedance (AI) model is key data for seismic interpretation, usually obtained from its nonlinear relation with seismic reflectivity. Common approaches use initial geological and seismic information to constraint the AI model estimation. When no accurate prior information is available, these approaches may dictate false results at some parts of the model. The regularization of ill-posed underdetermined problems requires some constraints to restrict the possible results. Available seismic inversion methods mostly use Tikhonov or total variation (TV) regularizations with some adjustments. Tikhonov regularization assumes smooth variation in the AI model, and it is incurious about the rapid changes in the model. TV allows rapid changes, and it is more stable in presence of noisy data. In a detailed realistic earth model that AI changes gradually, TV creates a stair-casing effect, which could lead to misinterpretation. This could be avoided by using TV and Tikhonov regularization sequentially in the alternating direction method of multipliers (ADMM) and creating the AI model. The result of implementing the proposed algorithm (STTVR) on 2D synthetic and real seismic sections shows that the smaller details in the lithological variations are accounted for as well as the general trend. STTVR can calculate major AI variations without any additional low-frequency constraints. The temporal and spatial transition of the calculated AI in real seismic data is gradual and close to a real geological setting.

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Quantitative interpretation using facies-based seismic inversion

Interpretation ◽

10.1190/int-2016-0178.1 ◽

2017 ◽

Vol 5 (3) ◽

pp. SL1-SL8 ◽

Cited By ~ 11

Author(s):

Ehsan Zabihi Naeini ◽

Russell Exley

Keyword(s):

Seismic Data ◽

Low Frequency ◽

Seismic Inversion ◽

Quantitative Interpretation ◽

Frequency Model ◽

Amplitude Variation With Offset ◽

Limited Bandwidth ◽

Seismic Amplitude ◽

Primary Signal

Quantitative interpretation (QI) is an important part of successful exploration, appraisal, and development activities. Seismic amplitude variation with offset (AVO) provides the primary signal for the vast majority of QI studies allowing the determination of elastic properties from which facies can be determined. Unfortunately, many established AVO-based seismic inversion algorithms are hindered by not fully accounting for inherent subsurface facies variations and also by requiring the addition of a preconceived low-frequency model to supplement the limited bandwidth of the input seismic. We apply a novel joint impedance and facies inversion applied to a North Sea prospect using broadband seismic data. The focus was to demonstrate the significant advantages of inverting for each facies individually and iteratively determine an optimized low-frequency model from facies-derived depth trends. The results generated several scenarios for potential facies distributions thereby providing guidance to future appraisal and development decisions.

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Seismic inversion of a carbonate buildup: A case study

Interpretation ◽

10.1190/int-2017-0081.1 ◽

2017 ◽

Vol 5 (4) ◽

pp. T641-T652 ◽

Cited By ~ 1

Author(s):

Mark Sams ◽

Paul Begg ◽

Timur Manapov

Keyword(s):

Seismic Data ◽

Probability Distributions ◽

Low Frequency ◽

Rock Physics ◽

Seismic Inversion ◽

Accurate Estimation ◽

Amplitude Analysis ◽

Simultaneous Inversion ◽

Band Limited ◽

Using Data

The information within seismic data is band limited and angle limited. Together with the particular physics and geology of carbonate rocks, this imposes limitations on how accurately we can predict the presence of hydrocarbons in carbonates, map the top carbonate, and characterize the porosity distribution through seismic amplitude analysis. Using data for a carbonate reef from the Nam Con Son Basin, Vietnam, the expectations based on rock-physics analysis are that the presence of gas can be predicted only when the porosity at the top of the carbonate is extremely high ([Formula: see text]), but that a fluid contact is unlikely to be observed in the background of significant porosity variations. Mapping the top of the carbonate (except when the top carbonate porosities are low) or a fluid contact requires accurate estimates of changes in [Formula: see text]. The seismic data do not independently support such an accurate estimation of sharp changes in [Formula: see text]. The standard approach of introducing low-frequency models and applying rock-physics constraints during a simultaneous inversion does not resolve the problems: The results are heavily biased by the well control and the initial interpretation of the top carbonate and fluid contact. A facies-based inversion in which the elastic properties are restricted to values consistent with the facies predicted to be present removes the well bias, but it does not completely obviate the need for a reasonably accurate initial interpretation in terms of prior facies probability distributions. Prestack inversion improves the quality of the facies predictions compared with a poststack inversion.

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High-resolution acoustic impedance inversion to characterize turbidites at Marlim Field, Campos Basin, Brazil

Interpretation ◽

10.1190/int-2013-0137.1 ◽

2014 ◽

Vol 2 (3) ◽

pp. T143-T153 ◽

Cited By ~ 8

Author(s):

Tatiane M. Nascimento ◽

Paulo T. L. Menezes ◽

Igor L. Braga

Keyword(s):

High Resolution ◽

Seismic Data ◽

Acoustic Impedance ◽

Structural Information ◽

Low Frequency ◽

Seismic Inversion ◽

Background Model ◽

Rock Properties ◽

High Porosity ◽

Campos Basin

Seismic inversion is routinely used to determine rock properties, such as acoustic impedance and porosity, from seismic data. Nonuniqueness of the solutions is a major issue. A good strategy to reduce this inherent ambiguity of the inversion procedure is to introduce stratigraphic and structural information a priori to better construct the low-frequency background model. This is particularly relevant when studying heterogeneous deepwater turbidite reservoirs that form prolific, but complex, hydrocarbon plays in the Brazilian offshore basins. We evaluated a high-resolution inversion workflow applied to 3D seismic data at Marlim Field, Campos Basin, to recover acoustic impedance and porosity of the turbidites reservoirs. The Marlim sandstones consist of an Oligocene/Miocene deepwater turbidite system forming a series of amalgamated bodies. The main advantage of our workflow is to incorporate the interpreter’s knowledge about the local stratigraphy to construct an enhanced background model, and then extract a higher resolution image from the seismic data. High-porosity zones were associated to the reservoirs facies; meanwhile, the nonreservoir facies were identified as low-porosity zones.

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Stuck between a rock and a reflection: A tutorial on low-frequency models for seismic inversion

Interpretation ◽

10.1190/int-2016-0150.1 ◽

2017 ◽

Vol 5 (2) ◽

pp. B17-B27 ◽

Cited By ~ 9

Author(s):

Mark Sams ◽

David Carter

Keyword(s):

Elastic Properties ◽

Model Building ◽

Seismic Velocity ◽

Low Frequency ◽

Rock Physics ◽

Frequency Component ◽

Seismic Inversion ◽

Rock Properties ◽

Seismic Velocities ◽

Frequency Model

Predicting the low-frequency component to be used for seismic inversion to absolute elastic rock properties is often problematic. The most common technique is to interpolate well data within a structural framework. This workflow is very often not appropriate because it is too dependent on the number and distribution of wells and the interpolation algorithm chosen. The inclusion of seismic velocity information can reduce prediction error, but it more often introduces additional uncertainties because seismic velocities are often unreliable and require conditioning, calibration to wells, and conversion to S-velocity and density. Alternative techniques exist that rely on the information from within the seismic bandwidth to predict the variations below the seismic bandwidth; for example, using an interpretation of relative properties to update the low-frequency model. Such methods can provide improved predictions, especially when constrained by a conceptual geologic model and known rock-physics relationships, but they clearly have limitations. On the other hand, interpretation of relative elastic properties can be equally challenging and therefore interpreters may find themselves stuck — unsure how to interpret relative properties and seemingly unable to construct a useful low-frequency model. There is no immediate solution to this dilemma; however, it is clear that low-frequency models should not be a fixed input to seismic inversion, but low-frequency model building should be considered as a means to interpret relative elastic properties from inversion.

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High resolution fixed-point seismic inversion

Interpretation ◽

10.1190/int-2020-0136.1 ◽

2021 ◽

pp. 1-54

Author(s):

Song Pei ◽

Xingyao Yin ◽

Zhaoyun Zong ◽

Kun Li

Keyword(s):

Fixed Point ◽

Objective Function ◽

Seismic Data ◽

Target Function ◽

Recursive Formula ◽

Frequency Component ◽

Seismic Inversion ◽

Inversion Method ◽

Good Convergence ◽

Band Limited

Resolution improvement always presents the crucial task in geological inversion. Band-limited characteristics of seismic data and noise make seismic inversion complicated. Specifically, geological inversion suffers from the deficiency of both low- and high-frequency components. We propose the fixed-point seismic inversion method to alleviate these issues. The problem of solving objective function is transformed into the problem of finding the fixed-point of objective function. Concretely, a recursive formula between seismic signal and reflection coefficient is established, which is characterized by good convergence and verified by model examples. The error between the model value and the inverted value is reduced to around zero after few iterations. The model examples show that in either case, that is, the seismic traces are noise-free or with a little noise, the model value can almost be duplicated. Even if the seismic trace is accompanied by the moderate noise, the optimal inverted results can still be obtained with the proposed method. The initial model constraint is further introduced into the objective function to increase the low-frequency component of the inverted results by adding prior information into the target function. The singular value decomposition (SVD) method is applied to the inversion framework, thus making a high improvement of anti-noise ability. At last, the synthetic models and seismic data are investigated following the proposed method. The inverted results obtained from the fixed-point seismic inversion are compared with those obtained from the conventional seismic inversion, and it is found that the former has a higher resolution than the latter.

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