Far-field superresolution by imaging of resonant multiples

Schuster, Gerard T.; Huang, Yunsong

doi:10.1093/gji/ggu350

Cited by 8 publications

(3 citation statements)

References 26 publications

(14 reference statements)

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“…If they occur in the background medium, multiples can enhance the illumination of certain wavenumbers in the spectrum of the model perturbation, leading to sinusoidal artifacts in FWI (Kazei, Kashtan, et al, ; Kazei et al, ). If the multiples are of a certain order and separated from other waves, then they can actually improve the resolution of the migration (Schuster & Huang, ). Multiple scattered waves may also enhance the illumination of deeper parts of the model in FWI (Alkhalifah & Plessix, ).…”

Section: Discussionmentioning

confidence: 99%

Scattering Radiation Pattern Atlas: What Anisotropic Elastic Properties Can Body Waves Resolve?

Kazei

Alkhalifah

2019

JGR Solid Earth

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Full‐waveform inversion (FWI) optimizes the subsurface properties of geophysical Earth models in such a way that the modeled data, based on these subsurface properties, match the observed data. The anisotropic properties, whether monoclinic, orthorhombic, triclinic, or vertical transversally isotropic (VTI), of the subsurface, be it a fractured reservoir or the core‐mantle boundary, are necessary to describe the observed wave phenomena. There are no principal limitations on the complexity of the anisotropy that can be inverted using FWI. However, the question remains—what kind of anisotropic descriptions of the elastic properties of the Earth can or cannot be inverted reliably from seismic waveforms? We reveal the resolution that can be achieved through reconstructions of each elastic parameter by building vertical resolution patterns from the scattering radiation patterns of body waves. A visual analysis of these patterns indicates “trade‐offs,” that is, perturbations of parameters that have the same reflection‐based scattering patterns as other perturbations. Each trade‐off leads to an apparent ambiguity in the inversion, which must be addressed by additional assumptions, constraints, or regularizations. For orthorhombic media, we find the exact trade‐offs that exist between parameters. Our parameterization isolates the VTI parameters, and therefore, we also obtain trade‐offs for every scattering mode for VTI media. We discover that only monoclinic parameters are recoverable from the first‐order scattering of monotypic waves. We summarize the trade‐offs in tables for easy reference. This paper is intended to be useful for researchers setting up anisotropic FWI problems, and interpreting or controlling the quality of such inversions.

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Section: Discussionmentioning

confidence: 99%

Scattering Radiation Pattern Atlas: What Anisotropic Elastic Properties Can Body Waves Resolve?

Kazei

Alkhalifah

2019

JGR Solid Earth

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“…Thus, the WDG method has the capability for high resolution imaging of the slab thickness. This is not too surprising because the steep part of the dispersion curves corresponds to nearly vertically incident waves, which generate resonant reflections that can provide superresolution imaging Schuster and Huang (2014).…”

Section: Resolution and Higher-order Modesmentioning

confidence: 99%

Dispersion inversion of guided P-waves in a waveguide of arbitrary geometry

Hanafy

Schuster

2018

SEG Technical Program Expanded Abstracts 2018

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“…Resonant multiples can be migrated to achieve better resolution than migrating primary reflections. In fact, the imaging resolution can be better than half of the wavelength so that this is considered super-resolution imaging (Schuster and Huang, 2014).…”

Section: Introductionmentioning

confidence: 99%

Prediction and Migration of Surface-related Resonant Multiples

Guo

Schuster

Huang

2015

SEG Technical Program Expanded Abstracts 2015

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SUMMARYSurface-related resonant multiples can be migrated to achieve better resolution than migrating primary reflections. We now derive the formula for migrating surface-related resonant multiples, and show its super-resolution characteristics. Moreover, a method is proposed to predict surface-related resonant multiples with zero-offset primary reflections. The prediction can be used to indentify and extract the true resonant multiple from other events. Both synthetic and field data are used to validate this prediction.

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Far-field superresolution by imaging of resonant multiples

Cited by 8 publications

References 26 publications

Scattering Radiation Pattern Atlas: What Anisotropic Elastic Properties Can Body Waves Resolve?

Scattering Radiation Pattern Atlas: What Anisotropic Elastic Properties Can Body Waves Resolve?

Dispersion inversion of guided P-waves in a waveguide of arbitrary geometry

Prediction and Migration of Surface-related Resonant Multiples

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