Through-Tubing Well Seismic: A Mast Campaign Across an Offshore Producing Field, Saudi Arabia-Kuwait Partitioned Neutral Zone

Kaoru Yamaguchi; Bernard G. Frignet

doi:10.2113/geoarabia0104571

Through-Tubing Well Seismic: A Mast Campaign Across an Offshore Producing Field, Saudi Arabia-Kuwait Partitioned Neutral Zone

GeoArabia ◽

10.2113/geoarabia0104571 ◽

1996 ◽

Vol 1 (4) ◽

pp. 571-582

Author(s):

Kaoru Yamaguchi ◽

Bernard G. Frignet

Keyword(s):

Arabian Gulf ◽

Seismic Source ◽

Velocity Model ◽

Data Availability ◽

Planning Stage ◽

Air Gun ◽

Local Experience ◽

Zero Offset ◽

Tube Wave ◽

Well Data

ABSTRACT A multi-well VSP Through-Tubing campaign was conducted in order to survey 2 neighboring mature fields in the northern Arabian Gulf. Nine key wells were selected by the reservoir engineers and geophysicists from a total of more than 200 wells. The selection criteria included: (1) spatial distribution; (2) previous well data availability; and (3) completion type. At the planning stage it was estimated that 3 days (excluding night work for safety) would be required per well (one day to rig-up the mast, one day to acquire the seismic data and one day to rig-down). Local experience indicated that a single air gun would be an effective seismic source. A slimhole, monocable, single-axis geophone sonde was selected as the downhole seismic tool. The zero-offset VSP configuration, with 80 foot level-spacing from total depth to surface was adopted. A supply boat was dedicated for the duration of the campaign. The actual operation was completed in 24 days, 3 days earlier than planned. An average of 90% of the VSP levels were found suitable for first break detection, which provided accurate Time-Depth curves for all 9 wells. Geophone coupling quality is dependent on the Tubing-Casing contact. The tube wave is developed at all 9 wells; but, overall 80% of the levels were selected for VSP processing. In 5 wells, where sonic logs had been acquired, synthetic seismograms were generated which confirmed the validity of VSP reflections. The data is now integrated in a 3-D velocity model.

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The Wolfspar experience with low-frequency seismic source field data: Motivation, processing, and implications

The Leading Edge ◽

10.1190/tle41010010.1 ◽

2022 ◽

Vol 41 (1) ◽

pp. 9-18

Author(s):

Andrew Brenders ◽

Joe Dellinger ◽

Imtiaz Ahmed ◽

Esteban Díaz ◽

Mariana Gherasim ◽

...

Keyword(s):

Gulf Of Mexico ◽

Seismic Data ◽

Field Data ◽

Model Building ◽

Low Frequency ◽

Seismic Source ◽

Velocity Model ◽

Seismic Sources ◽

Velocity Model Building ◽

Air Gun

The promise of fully automatic full-waveform inversion (FWI) — a (seismic) data-driven velocity model building process — has proven elusive in complex geologic settings, with impactful examples using field data unavailable until recently. In 2015, success with FWI at the Atlantis Field in the U.S. Gulf of Mexico demonstrated that semiautomatic velocity model building is possible, but it also raised the question of what more might be possible if seismic data tailor-made for FWI were available (e.g., with increased source-receiver offsets and bespoke low-frequency seismic sources). Motivated by the initial value case for FWI in settings such as the Gulf of Mexico, beginning in 2007 and continuing into 2021 BP designed, built, and field tested Wolfspar, an ultralow-frequency seismic source designed to produce seismic data tailor-made for FWI. A 3D field trial of Wolfspar was conducted over the Mad Dog Field in the Gulf of Mexico in 2017–2018. Low-frequency source (LFS) data were shot on a sparse grid (280 m inline, 2 to 4 km crossline) and recorded into ocean-bottom nodes simultaneously with air gun sources shooting on a conventional dense grid (50 m inline, 50 m crossline). Using the LFS data with FWI to improve the velocity model for imaging produced only incremental uplift in the subsalt image of the reservoir, albeit with image improvements at depths greater than 25,000 ft (approximately 7620 m). To better understand this, reprocessing and further analyses were conducted. We found that (1) the LFS achieved its design signal-to-noise ratio (S/N) goals over its frequency range; (2) the wave-extrapolation and imaging operators built into FWI and migration are very effective at suppressing low-frequency noise, so that densely sampled air gun data with a low S/N can still produce useable model updates with low frequencies; and (3) data density becomes less important at wider offsets. These results may have significant implications for future acquisition designs with low-frequency seismic sources going forward.

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2.5-D true‐amplitude Kirchhoff migration to zero offset in laterally inhomogeneous media

Geophysics ◽

10.1190/1.1444356 ◽

1998 ◽

Vol 63 (2) ◽

pp. 557-573 ◽

Cited By ~ 31

Author(s):

Martin Tygel ◽

Jörg Schleicher ◽

Peter Hubral ◽

Lúcio T. Santos

Keyword(s):

Seismic Source ◽

Velocity Model ◽

Dynamic Effects ◽

Geometrical Spreading ◽

Spreading Factor ◽

Seismic Section ◽

Kirchhoff Migration ◽

Reflection Angle ◽

Earth Models ◽

Zero Offset

The proposed new Kirchhoff‐type true‐amplitude migration to zero offset (MZO) for 2.5-D common‐offset reflections in 2-D laterally inhomogeneous layered isotropic earth models does not depend on the reflector curvature. It provides a transformation of a common‐offset seismic section to a simulated zero‐offset section in which both the kinematic and main dynamic effects are accounted for correctly. The process transforms primary common‐offset reflections from arbitrary curved interfaces into their corresponding zero‐offset reflections automatically replacing the geometrical‐spreading factor. In analogy to a weighted Kirchhoff migration scheme, the stacking curve and weight function can be computed by dynamic ray tracing in the macro‐velocity model that is supposed to be available. In addition, we show that an MZO stretches the seismic source pulse by the cosine of the reflection angle of the original offset reflections. The proposed approach quantitatively extends the previous MZO or dip moveout (DMO) schemes to the 2.5-D situation.

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The shape of things to come — Development and testing of a new marine vibrator source

The Leading Edge ◽

10.1190/tle38090680.1 ◽

2019 ◽

Vol 38 (9) ◽

pp. 680-690 ◽

Cited By ~ 1

Author(s):

Benoît Teyssandier ◽

John J. Sallas

Keyword(s):

Seismic Source ◽

Test Facility ◽

Data Sets ◽

Far Field ◽

Ocean Bottom ◽

Air Gun ◽

Seismic Image ◽

Field Radiation ◽

Technical Issues ◽

To Come

Ten years ago, CGG launched a project to develop a new concept of marine vibrator (MV) technology. We present our work, concluding with the successful acquisition of a seismic image using an ocean-bottom-node 2D survey. The expectation for MV technology is that it could reduce ocean exposure to seismic source sound, enable new acquisition solutions, and improve seismic data quality. After consideration of our objectives in terms of imaging, productivity, acoustic efficiency, and operational risk, we developed two spectrally complementary prototypes to cover the seismic bandwidth. In practice, an array composed of several MV units is needed for images of comparable quality to those produced from air-gun data sets. Because coupling to the water is invariant, MV signals tend to be repeatable. Since far-field pressure is directly proportional to piston volumetric acceleration, the far-field radiation can be well controlled through accurate piston motion control. These features allow us to shape signals to match precisely a desired spectrum while observing equipment constraints. Over the last few years, an intensive validation process was conducted at our dedicated test facility. The MV units were exposed to 2000 hours of in-sea testing with only minor technical issues.

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Gaussian beam migration

Geophysics ◽

10.1190/1.1442788 ◽

1990 ◽

Vol 55 (11) ◽

pp. 1416-1428 ◽

Cited By ~ 293

Author(s):

N. Ross Hill

Keyword(s):

Gaussian Beam ◽

Wave Field ◽

Seismic Source ◽

Velocity Model ◽

Downward Continuation ◽

Gaussian Beams ◽

Seismic Velocities ◽

Migration Method ◽

Gaussian Beam Migration ◽

Lateral Variations

Just as synthetic seismic data can be created by expressing the wave field radiating from a seismic source as a set of Gaussian beams, recorded data can be downward continued by expressing the recorded wave field as a set of Gaussian beams emerging at the earth’s surface. In both cases, the Gaussian beam description of the seismic‐wave propagation can be advantageous when there are lateral variations in the seismic velocities. Gaussian‐beam downward continuation enables wave‐equation calculation of seismic propagation, while it retains the interpretive raypath description of this propagation. This paper describes a zero‐offset depth migration method that employs Gaussian beam downward continuation of the recorded wave field. The Gaussian‐beam migration method has advantages for imaging complex structures. Like finite‐difference migration, it is especially compatible with lateral variations in velocity, but Gaussian beam migration can image steeply dipping reflectors and will not produce unwanted reflections from structure in the velocity model. Unlike other raypath methods, Gaussian beam migration has guaranteed regular behavior at caustics and shadows. In addition, the method determines the beam spacing that ensures efficient, accurate calculations. The images produced by Gaussian beam migration are usually stable with respect to changes in beam parameters.

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Travel Time Tomography to Delineate 3-D Regional Seismic Velocity Structure in the Banyumas Basin, Central Java, Indonesia, Using Dense Borehole Seismographic Stations

Frontiers in Earth Science ◽

10.3389/feart.2021.639271 ◽

2021 ◽

Vol 9 ◽

Author(s):

Hidayat Hidayat ◽

Andri Dian Nugraha ◽

Awali Priyono ◽

Marjiyono Marjiyono ◽

Januar H. Setiawan ◽

...

Keyword(s):

Velocity Structure ◽

Seismic Velocity ◽

Velocity Model ◽

Crustal Layer ◽

Central Java ◽

Resolution Element ◽

Passive Seismic ◽

Dextral Strike Slip Fault ◽

Southern Central ◽

Well Data

The Banyumas Basin is a tertiary sedimentary basin located in southern Central Java, Indonesia. Due to the presence of volcanic deposits, 2-D seismic reflection methods cannot provide a good estimation of the sediment thickness and the subsurface geology structure in this area. In this study, the passive seismic tomography (PST) method was applied to image the 3-D subsurface Vp, Vs, and Vp/Vs ratio. We used 70 seismograph borehole stations with a recording duration of 177 days. A total of 354 events with 9, 370 P and 9, 368 S phases were used as input for tomographic inversion. The checkshot data of a 4, 400-meter deep exploration well (Jati-1) located within the seismic network were used to constrain the shallow crustal layer of the initial 1-D velocity model. The model resolution of the tomographic inversions was assessed using the checkerboard resolution test (CRT), the diagonal resolution element (DRE), and the derivative weight sum (DWS). Using the obtained Vp, Vs, and Vp/Vs ratio, we were able to sharpen details of the geological structures within the basin from previous geological studies, and a fault could be well-imaged at a depth of 4 km. We interpreted this as the main dextral strike-slip fault that controls the pull apart process of the Banyumas Basin. The thickness of the sediment layers, as well as its layering, were also could be well determined. We found prominent features of the velocity contrast that aligned very well with the boundary between the Halang and Rambatan formations as observed in the Jati-1 well data. Furthermore, an anticline structure, which is a potential structural trap for the petroleum system in the Banyumas Basin, was also well imaged. This was made possible due to the dense borehole seismographic stations which were deployed in the study area.

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Some notes on air-gun development as a marine seismic source

The Leading Edge ◽

10.1190/1.3259610 ◽

2009 ◽

Vol 28 (11) ◽

pp. 1334-1335 ◽

Cited By ~ 1

Author(s):

Ben F. Giles

Keyword(s):

Seismic Source ◽

Air Gun ◽

Marine Seismic

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Far-offset detection of normal modes and diving waves: a case study in Valhall, southern North Sea

Geophysics ◽

10.1190/geo2021-0267.1 ◽

2021 ◽

pp. 1-50

Author(s):

Filipe Borges ◽

Martin Landrø

Keyword(s):

Normal Modes ◽

Seismic Source ◽

Velocity Model ◽

Seismic Survey ◽

The Past ◽

Lack Of Control ◽

Record Data ◽

Refracted Waves ◽

1D Velocity Model

The use of permanent arrays for continuous reservoir monitoring has become a reality in the past decades, with Ekofisk and Valhall being its flagships. One of the possibilities when such solution is available is to passively record data while acquisitions with an active source are ongoing in nearby areas. These recordings might contain ultrafar-offset data (over 30 km), which are hardly used in standard reservoir exploration and monitoring, as they are mostly a combination of normal modes, deep reflections and diving waves. We present here data from the Valhall Life of Field Seismic array, recorded while an active seismic survey was being acquired in Ekofisk, in April 2014. Despite the lack of control on source firing time and position, analysis of the data shows that the normal modes are remarkably clear, overcoming the ambient noise in the field. The normal modes can be well explained by a two-layer acoustic model, while a combination of diving waves and refracted waves can be fairly well reproduced with a regional 1D velocity model. We suggest a method to use the far-offset recordings to monitor changes in the shallow sediments between source and receivers, both with and without a coherent seismic source in the area.

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Design of Near-orthogonal Air-gun Sequences for Marine Seismic Source Encoding

78th EAGE Conference and Exhibition 2016 ◽

10.3997/2214-4609.201600948 ◽

2016 ◽

Author(s):

M.B. Mueller ◽

D.F. Halliday ◽

D.J. van Manen ◽

J.O.A. Robertsson

Keyword(s):

Seismic Source ◽

Air Gun ◽

Marine Seismic ◽

Source Encoding

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Overcoming the challenges of a shallow-water sparse wide-azimuth survey to improve deep reservoir imaging in the East China Sea

The Leading Edge ◽

10.1190/tle38080610.1 ◽

2019 ◽

Vol 38 (8) ◽

pp. 610-616

Author(s):

Yun Wei ◽

Hua Chen ◽

Senqing Hu ◽

Peipei Deng ◽

Yongdeng Xiao ◽

...

Keyword(s):

Shallow Water ◽

East China Sea ◽

Three Dimensional ◽

Water Layer ◽

Velocity Model ◽

East China ◽

The East China Sea ◽

China Sea ◽

Well Data ◽

The Impact

A new broadband wide-azimuth towed-streamer (WATS) survey was acquired to better resolve reservoir compartments in a shallow-water region of the East China Sea. To offset the shortcomings of narrow-azimuth acquisition along the strike direction, two vessels were added side-by-side as additional source vessels to form the WATS acquisition geometry for this survey. This WATS acquisition was much sparser than typical WATS surveys used in deepwater environments due to its one-sided configuration. The combination of sparse acquisition, shallow water, and deep targets set the challenge of how to optimally reveal the potential of side-gun data to improve the final image. Three-dimensional effects and severe aliasing in the crossline direction pose significant challenges for side-gun data processing. We present a comprehensive workflow to resolve these challenges consisting of 3D deghosting, 3D model-based water-layer demultiple, 3D surface-related multiple elimination, and 4D regularization for sparse and shallow-water wide-azimuth data. A tilted orthorhombic velocity model is built with better constraints from the wide-azimuth data, leading to improved fault positioning and imaging. Side-gun data clearly enhance the final target reservoir image and tie better with well data due to improved illumination. A new channel is discovered based on interpretation from the inverted VP/VS, explaining the previous incorrect prediction for one failed well that was drilled into a thinner and shallower channel unconnected to the main reservoir. An analysis of the impact of side-gun data from different offsets and azimuths shows that better azimuthal distribution within middle offset ranges had a more significant impact than far offsets in the final image of this survey. This information provides valuable reference in similar geologic conditions for future acquisition designs.

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2-D continuation operators and their applications

Geophysics ◽

10.1190/1.1444100 ◽

1996 ◽

Vol 61 (6) ◽

pp. 1846-1858 ◽

Cited By ~ 31

Author(s):

Claudio Bagaini ◽

Umberto Spagnolini

Keyword(s):

Seismic Data ◽

Real Data ◽

Integral Form ◽

Amplitude Distribution ◽

Velocity Model ◽

Velocity Analysis ◽

Seismic Data Processing ◽

Analysis Method ◽

Standard Tool ◽

Zero Offset

Continuation to zero offset [better known as dip moveout (DMO)] is a standard tool for seismic data processing. In this paper, the concept of DMO is extended by introducing a set of operators: the continuation operators. These operators, which are implemented in integral form with a defined amplitude distribution, perform the mapping between common shot or common offset gathers for a given velocity model. The application of the shot continuation operator for dip‐independent velocity analysis allows a direct implementation in the acquisition domain by exploiting the comparison between real data and data continued in the shot domain. Shot and offset continuation allow the restoration of missing shot or missing offset by using a velocity model provided by common shot velocity analysis or another dip‐independent velocity analysis method.

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