Source-receiver, reverse-time imaging of dual-source, vector-acoustic seismic data

Vasconcelos, Ivan

doi:10.1190/geo2012-0300.1

Cited by 50 publications

(25 citation statements)

References 42 publications

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“…Note that here we use a monopole-type source, but with the recent introduction of dual-source technology that combines pressure with gradient/dipole marine sources , handling of ingoing and outgoing waves at the source array will also be possible in the near future by combining the extrapolated receiver fields together with monopole and dipole source side propagators as explained by Vasconcelos (2013). An imaging condition is finally used to map the interaction of source and receiver wavefields in the subsurface and create a representation of the earth's physical property contrasts:…”

Section: A Review Of Vector-acoustic Migrationmentioning

confidence: 98%

“…Shot-profile VARTM (see Appendix A for a vector-acoustic derivation of receiver-profile migration) solves the injection limitations of standard RTM without requiring any preprocessing of the data (Vasconcelos, 2013). Simultaneous injection (indicated by the & symbol in the following equation) of the full pressure and (negative) normal particle velocity with two different types of injection sources, dipole and monopole respectively, enables "on-the-fly" wavefield separation into the up-and downgoing components of the recorded field, with upgoing waves that are injected only downward and downgoing waves that back-propagate only upward:…”

Section: A Review Of Vector-acoustic Migrationmentioning

confidence: 99%

“…To perform mirror imaging, the free surface is removed and the receiver extrapolation domain is extended to a depth of −4.5 km with a wavespeed model in the negative depths that is a mirrored version of the migration velocity model with respect to the free surface (Vasconcelos, 2013). This allows the arrivals related to the ghost wavefield in Figure 3b to continue propagating upward toward negative depths; the final ghost receiver wavefield at negative depths is reflected to positive depths prior to imaging using the same source wavefield as that used for the upgoing images.…”

Section: Mirror Imaging Of Downgoing Fieldsmentioning

confidence: 99%

“…In the context of source-receiver interferometric imaging (Oristaglio, 1989;Halliday and Curtis, 2010), Vasconcelos (2013) formulates migration in a VA fashion and shows that VA reverse time migration (VARTM) can produce images deprived of ghost reflectors, even when taking as input non-decomposed data. The The University of Edinburgh, School of GeoSciences, Edinburgh, UK.…”

Section: Introductionmentioning

confidence: 99%

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Vector-acoustic reverse time migration of Volve ocean-bottom cable data set without up/down decomposed wavefields

et al. 2015

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Methods for wavefield injection are commonly used to extrapolate seismic data in reverse time migration (RTM). Injecting a single component of the acoustic field, for example, pressure, leads to ambiguity in the direction of propagation. Each recorded wavefront is propagated both upward and downward, and spurious (or ghost) reflectors are created alongside real reflectors in the subsurface image. Thus, wavefield separation based on the combination of pressure and particle velocity data is generally performed prior to imaging to extract only the upgoing field from multicomponent seabed or towed marine seismic recordings. By instead combining vector-acoustic (VA) data with monopoleand dipole-type propagators in the extrapolation of shot or receiver gathers, we show that wavefield separation (or deghosting) can instead be performed "on-the-fly" at limited additional cost. This strategy was successfully applied to a line of a North Sea ocean-bottom cable data set, acquired over the Volve field. We then evaluate additional advantages over standard RTM with decomposed fields such as improved handling of the directivity information contained in the acquired VA data for clearer shallow sections and better focused space-lag common image gathers, and imaging of the downgoing component without the need for additional finite-difference modeling via mirror migration. Finally, we prove the robustness of our method with respect to sparse and irregular receiver sampling.

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Section: A Review Of Vector-acoustic Migrationmentioning

confidence: 98%

Section: A Review Of Vector-acoustic Migrationmentioning

confidence: 99%

Section: Mirror Imaging Of Downgoing Fieldsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Vector-acoustic reverse time migration of Volve ocean-bottom cable data set without up/down decomposed wavefields

et al. 2015

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“…However, for nonlinear applications, it can be useful to use the redatumed data R ∪ ðx i ; x 0 i ; tÞ and R ∩ ðx j ; x 0 j ; tÞ at two different depth levels ∂D i and ∂D j (with x 3;j > x 3;i ). For example, these responses can be used as input for a new nonlinear imaging method, as introduced by Fleury and Vasconcelos (2012), Ravasi and Curtis (2013), and Vasconcelos (2013) or for full-waveform inversion (Virieux and Operto, 2009), to resolve the parameters of the target zone between these depth levels. Van der Neut et al (2013) discuss an alternative method to combine imaging from above with imaging from below.…”

Section: Imaging From Belowmentioning

confidence: 99%

Marchenko imaging

et al. 2014

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Traditionally, the Marchenko equation forms a basis for 1D inverse scattering problems. A 3D extension of the Marchenko equation enables the retrieval of the Green’s response to a virtual source in the subsurface from reflection measurements at the earth’s surface. This constitutes an important step beyond seismic interferometry. Whereas seismic interferometry requires a receiver at the position of the virtual source, for the Marchenko scheme it suffices to have sources and receivers at the surface only. The underlying assumptions are that the medium is lossless and that an estimate of the direct arrivals of the Green’s function is available. The Green’s function retrieved with the 3D Marchenko scheme contains accurate internal multiples of the inhomogeneous subsurface. Using source-receiver reciprocity, the retrieved Green’s function can be interpreted as the response to sources at the surface, observed by a virtual receiver in the subsurface. By decomposing the 3D Marchenko equation, the response at the virtual receiver can be decomposed into a downgoing field and an upgoing field. By deconvolving the retrieved upgoing field with the downgoing field, a reflection response is obtained, with virtual sources and virtual receivers in the subsurface. This redatumed reflection response is free of spurious events related to internal multiples in the overburden. The redatumed reflection response forms the basis for obtaining an image of a target zone. An important feature is that spurious reflections in the target zone are suppressed, without the need to resolve first the reflection properties of the overburden.

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Constructing new seismograms from old earthquakes: Retrospective seismology at multiple length scales

et al. 2015

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If energy emitted by a seismic source such as an earthquake is recorded on a suitable backbone array of seismometers, source‐receiver interferometry (SRI) is a method that allows those recordings to be projected to the location of another target seismometer, providing an estimate of the seismogram that would have been recorded at that location. Since the other seismometer may not have been deployed at the time at which the source occurred, this renders possible the concept of “retrospective seismology” whereby the installation of a sensor at one period of time allows the construction of virtual seismograms as though that sensor had been active before or after its period of installation. Here we construct such virtual seismograms on target sensors in both industrial seismic and earthquake seismology settings, using both active seismic sources and ambient seismic noise to construct SRI propagators, and on length scales ranging over 5 orders of magnitude from ∼40 m to ∼2500 km. In each case we compare seismograms constructed at target sensors by SRI to those actually recorded on the same sensors. We show that spatial integrations required by interferometric theory can be calculated over irregular receiver arrays by embedding these arrays within 2‐D spatial Voronoi cells, thus improving spatial interpolation and interferometric results. The results of SRI are significantly improved by restricting the backbone receiver array to include approximately those receivers that provide a stationary‐phase contribution to the interferometric integrals. Finally, we apply both correlation‐correlation and correlation‐convolution SRI and show that the latter constructs fewer nonphysical arrivals.

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Source-receiver, reverse-time imaging of dual-source, vector-acoustic seismic data

Cited by 50 publications

References 42 publications

Vector-acoustic reverse time migration of Volve ocean-bottom cable data set without up/down decomposed wavefields

Vector-acoustic reverse time migration of Volve ocean-bottom cable data set without up/down decomposed wavefields

Marchenko imaging

Constructing new seismograms from old earthquakes: Retrospective seismology at multiple length scales

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