Conditional stochastic inversion of common-offset ground-penetrating radar reflection data

Xu, Zhanya; Irving, James; Yu, Lie; Zhu, Peimin; Holliger, Klaus

doi:10.1190/geo2020-0639.1

Cited by 7 publications

(12 citation statements)

References 64 publications

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“…A search of the phase rotation angle that maximizes the kurtosis when applied to this minimum-phase wavelet is then used to obtain the final mixed-phase GPR source wavelet. The practical validity of this source wavelet estimation procedure was recently demonstrated by Xu et al (2021). Note that the effects of minor dispersion in the GPR data are, at least in part, accounted for in the sense that an effective wavelet that best fits the considered dataset in its entirety, rather than the true emitted GPR source signal, is estimated.…”

Section: Velocity Perturbation Inversionmentioning

confidence: 93%

“…The comparison with the reference velocity model (Figure 2a) is quite favorable, which clearly illustrates the potential benefits of the proposed diffraction-and reflection-based velocity estimation approach. In this context, is important to emphasize that the former can only resolve the smooth large-scale velocity structure and, hence, entirely misses the presence of the thin bed (e.g., Yuan et al 2019) whereas, on its own, the latter requires coincident borehole information for calibration and recovery of the large-scale component of the velocity structure (e.g., Schmelzbach et al 2012;Xu et al 2021).…”

Section: Layered Modelmentioning

confidence: 99%

“…The surficial aquifer consists of late Quaternary fluvial deposits dominated by gravel and sand, and is underlain by a layer of red clay at ~20 m depth (Barrash & Clemo 2002). The depth of the groundwater table at the site varies seasonally between ~2 m and ~4 m. Over the past two decades, the BHRS has been extensively utilized for the testing, validation, and improvement of a wide variety of geophysical and hydrogeological characterization methods (e.g., Tronicke et al 2004;Bradford et al 2009;Dafflon et al 2009Dafflon et al , 2011Hochstetler et al 2016;Xu et al 2020Xu et al , 2021.…”

Section: Databasementioning

confidence: 99%

“…Zeng et al (2015) and Liu et al (2018) adopt similar approaches to estimate the distribution of soil water content and to characterize buried archaeological remains, respectively. Xu et al (2021) also assume a convolution model for the GPR traces, but combine stochastic simulation with simulated annealing optimization in order to generate velocity realizations that honor the GPR measurements and borehole porosity log data along the profile. Forte et al (2013; assume a locally 1D layered subsurface structure and use picked reflection amplitudes to recursively estimate the GPR velocity in a series of identified subsurface layers, in which the velocity is assumed constant.…”

Section: Introductionmentioning

confidence: 99%

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High-resolution velocity estimation from surface-based common-offset GPR reflection data

Irving

Holliger

2022

Geophysical Journal International

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Summary Surface-based common-offset ground-penetrating radar (GPR) reflection profiling is a popular geophysical exploration technique for obtaining high-resolution images of the shallow subsurface in a cost-effective manner. One drawback of this technique is that, without complementary borehole information in form of dielectric permittivity and/or porosity logs along the profile, it is currently not possible to obtain reliable estimates of the high-frequency electromagnetic velocity distribution of the probed subsurface region. This is problematic because adequate knowledge of the velocity is needed for accurate imaging and depth conversion of the data, as well as for quantifying the distribution of soil water content. To overcome this issue, we have developed a novel methodology for estimating the detailed subsurface velocity structure from common-offset GPR reflection measurements, which does not require additional conditioning information. The proposed approach combines two key components: Diffraction analysis is used to infer the smooth, large-scale component of the velocity distribution, whereas the superimposed small-scale fluctuations are inferred via inversion of the reflected wavefield. We test and validate our method on two synthetic datasets having increasing degrees of complexity and realism before applying it to a field example from the Boise Hydrogeophysical Research Site (BHRS), where independent control data in the form of neutron-neutron porosity logs are available for validation. The results obtained demonstrate the viability and robustness of the proposed approach. Further, due to its efficiency, both in terms of field effort and computational cost, the method can be readily extended to 3D, which further enhances its attractiveness compared to multi-offset-based GPR velocity estimation techniques.

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Section: Velocity Perturbation Inversionmentioning

confidence: 93%

Section: Layered Modelmentioning

confidence: 99%

Section: Databasementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High-resolution velocity estimation from surface-based common-offset GPR reflection data

Irving

Holliger

2022

Geophysical Journal International

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show abstract

“…In the same way, surface multiples, which are events that are reflected twice in the subsurface with a reflection at the air-ice interface in between before being recorded, will also be absent. To our knowledge, such secondary scattering is rather rare in GPR data, as evidenced by the great success of single-scatteringbased algorithms for the processing and analysis of GPR data (Irving et al, 2009;Schmelzbach et al, 2012;Xu et al, 2020Xu et al, , 2021Liu et al, 2022).…”

Section: Assumptions and Limitationsmentioning

confidence: 99%