True-amplitude one-way wave equation migration in the mixed domain

Vivas, Flor A.; Pestana, Reynam C.

doi:10.1190/1.3478574

Cited by 10 publications

(4 citation statements)

References 12 publications

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“…From equation 20, the proposed one-way propagator is composed of two terms: transmission-coefficient-compensating amplitudes, and conventional FFD propagator governing amplitudes and phases. Consequently, the algorithm structure might allow the compensation term (equation 21) to be incorporated into other phaseshift operators in the mixed domain, e.g., split-step Fourier method (Stoffa et al, 1990) for media with a weak lateral velocity contrast, a generalized screen propagator (de Hoop et al, 2000), or even amplitude-preserving one-way propagators (Zhang et al, 2005;Vivas and Pestana, 2010). However, this needs to be verified in the future, for it is not the focus of this paper.…”

Section: Theorymentioning

confidence: 95%

“…Most current true-amplitude migration algorithms include only geometrical spreading (Zhang et al, 2003(Zhang et al, , 2005Vivas and Pestana, 2010), and Q-compensation based on one-way wave-equation migration has been discussed by many authors (Dai and West, 1994;Mittet et al, 1995;Valenciano et al, 2011;Wang, 2008;Yu et al, 2002), but transmission losses during migration have been paid little attention. Deng and McMechan (2007) presented a twopass recursive algorithm to compensate for transmission losses using the framework of full-wave prestack reverse time migration (RTM) (Chang and McMechan, 1986).…”

Section: Introductionmentioning

confidence: 99%

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Compensation for transmission losses based on one-way propagators in the mixed domain

Sun

2012

GEOPHYSICS

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Most true-amplitude migration algorithms based on oneway wave equations involve corrections of geometric spreading and seismic Q attenuation. However, few papers discuss the compensation of transmission losses (CTL) based on one-way wave equations. Here, we present a method to compensate for transmission losses using one-way wave propagators for a 2D case. The scheme is derived from the Lippmann-Schwinger integral equation. The CTL scheme is composed of a transmission term and a phase-shift term. The transmission term compensates amplitudes while the wave propagates through subsurfaces. The transmission term is a function of the vertical wavenumbers of two adjacent heterogeneous screens. The phase-shift term is a Fourier finite-difference (FFD) propagator implemented in a mixed domain via Fourier transform. The transmission term can be flexibly incorporated into the conventional phaseshift migration algorithm, i.e., FFD, at every depth step. We analyze the effects of frequency, lateral velocity contrast, and vertical velocity ratio on the accuracy of the presented formulae. Numerical examples from a flat model and a fault model with lateral velocity variations are presented to demonstrate the ability of the proposed scheme for compensation of transmission losses.

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Section: Theorymentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Compensation for transmission losses based on one-way propagators in the mixed domain

Sun

2012

GEOPHYSICS

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“…Some researchers have done a great deal of work in solving one-way true amplitude equations to produce satisfactory imaging results [23,24], for example, the beamlet propagator is combined with it [25]. As mentioned above, based on the achievements of one-way wave equation migration, the theories of approximation, such as Taylor expansion, are used to solve one-way true amplitude equations [26][27][28][29]. In order to solve the issue of the limited imaging angle, ref.…”

Section: Introductionmentioning

confidence: 99%

Amplitude-Preserved Wave Equation: An Example to Image the Gas Hydrate System

et al. 2021

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Natural gas hydrate is an important energy source. Therefore, it is extremely important to provide a clear imaging profile to determine its distribution for energy exploration. In view of the problems existing in conventional migration methods, e.g., the limited imaging angles, we proposed to utilize an amplitude-preserved one-way wave equation migration based on matrix decomposition to deal with primary and multiple waves. With respect to seismic data gathered at the Chilean continental margin, a conventional processing flow to obtain seismic records with a high signal-to-noise ratio is introduced. Then, the imaging results of the conventional and amplitude-preserved one-way wave equation migration methods based on primary waves are compared, to demonstrate the necessity of implementing amplitude-preserving migration. Moreover, a simple two-layer model is imaged by using primary and multiple waves, which proves the superiority of multiple waves in imaging compared with primary waves and lays the foundation for further application. For the real data, the imaging sections of primary and multiple waves are compared. We found that multiple waves are able to provide a wider imaging illumination while primary waves fail to illuminate, especially for the imaging of bottom simulating reflections (BSRs), because multiple waves have a longer travelling path and carry more information. By imaging the actual seismic data, we can make a conclusion that the imaging result generated by multiple waves can be viewed as a supplementary for the imaging result of primary waves, and it has some guiding values for further hydrate and in general shallow gas exploration.

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“…The OWWE do not propagate the wave field amplitudes properly (Wapenaar, 1990;Godin, 1999) and must therefore, be modified by introducing in the equations a new operator which includes lateral and vertical gradients of the velocity field. The new resulting equations are known as One-Way Wave Equation with True Amplitude (OWWE -TA) (Zhang, 1993;Zhang, Zhang & Bleistein, 2003;Vivas & Pestana, 2010).…”

Section: Introductionmentioning

confidence: 99%

Deconvolution-type imaging condition effects on shot-profile migration amplitudes

Vivas-Mejía

González-Alvarez

Jaimes-Osorio³

et al. 2012

CT&F Cienc. Tecnol. Futuro

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Amplitude preservation in Pre-Stack Depth Migration (PSDM) processes that use wavefield extrapolation must be ensured – first, in the operators used to continue the wavefield in time or depth, and second, in the imaging condition used to estimate the reflectivity function. In the later point, the conventional correlation-type imaging condition must be replaced by a deconvolution-type imaging condition. Migration performed in common-shot profile domain obtains the final migrated image as the superposition of images resulting of migrate each shot separately. The amplitude obtained in a point of the migrated image corresponds to the sum of the reflectivities for each shot which has illuminated such point, along the angles determined by the velocity model and the positions of the source and the receiver. The deeper the reflector, the lower the amplitude of the illumination field will be. As result, the correlation-type imaging condition produces images with an unbalanced amplitude decrease with depth. A deconvolution-type imaging condition scales the amplitudes through a correlation, using the weighting function dependent on the spectral density or the illumination of the downgoing wave field. In this article, two possible scaling functions have been used in the case of a single shot. In the case of data with multiple shots, five scaling possibilities are presented with the spectral density or the illumination function. The results of applying these imaging conditions to synthetic data with multiple shots show that the values of the amplitude in the migrated images are influenced by the coverage of the common midpoint, compensating this effect only in one of the imaging conditions described. Numerical experiments with synthetic data generated using Seismic Unix and the Sigsbee2a data are presented, highlighting that in velocity fields with strong vertical and lateral velocity variations, the balance of the amplitudes of the deep reflectors relative to the shallow reflectors is strongly influenced by the imaging condition applied.

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True-amplitude one-way wave equation migration in the mixed domain

Cited by 10 publications

References 12 publications

Compensation for transmission losses based on one-way propagators in the mixed domain

Compensation for transmission losses based on one-way propagators in the mixed domain

Amplitude-Preserved Wave Equation: An Example to Image the Gas Hydrate System

Deconvolution-type imaging condition effects on shot-profile migration amplitudes

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