Abstract
The crosshole ground penetrating radar (GPR) is a widely used tool to map subsurface properties, and inversion methods are used to derive electrical parameters from crosshole GPR data. In this paper, a probabilistic inversion algorithm that uses Markov chain Monte Carlo (MCMC) simulations within the Bayesian framework is implemented to infer the posterior distribution of the relative permittivity of the subsurface medium. Close attention is paid to the critical elements of this method, including the forward model, data type and prior information, and their influence on the inversion results are investigated. First, a uniform prior distribution is used to reflect the lack of prior knowledge of model parameters, and inversions are performed using the straight-ray model with first-arrival traveltime data, the finite-difference time-domain (FDTD) model with first-arrival traveltime data, and the FDTD model with waveform data, respectively. The cases using first-arrival traveltime data require an unreasonable number of model evaluations to converge, yet are not able to recover the real relative permittivity field. In contrast, the inversion using the FDTD model with waveform data successfully infers the correct model parameters. Then, the smooth constraint of model parameters is employed as the prior distribution. The inversion results demonstrate that the prior information barely affects the inversion results using the FDTD model with waveform data, but significantly improves the inversion results using first-arrival traveltime data by decreasing the computing time and reducing uncertainties of the posterior distribution of model parameters.
Highlights
The crosshole ground penetrating radar (GPR) method has been widely applied for geological, environmental, and engineering investigations to characterize subsurface properties [1,2,3,4,5,6]
Based on the previous research, this paper focuses on the key elements of probabilistic inversion of crosshole GPR data, and systematically investigates the impact of the forward model, data type, and prior information on the inversion results
The results indicate that, without additional knowledge, the first-arrival traveltime data are unable to provide sufficient information to infer the model parameters
Summary
The crosshole ground penetrating radar (GPR) method has been widely applied for geological, environmental, and engineering investigations to characterize subsurface properties [1,2,3,4,5,6]. The ray-based forward models are usually computational efficient, yet utilize only a small portion of the measured data that may bias the inversion result [21]. A Bayesian inversion method was developed to infer the relative permittivity values of underground structures from crosshole GPR data [25]. This method used the FDTD forward simulator with waveform data and achieved better accuracy than the traditional ray tomography. Based on the previous research, this paper focuses on the key elements of probabilistic inversion of crosshole GPR data, and systematically investigates the impact of the forward model, data type, and prior information on the inversion results. This paper is concluded with a summary of the main findings
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